eri/nrc 02-202, accident source terms for light-water nuclear power plants
TRANSCRIPT
ERIINRC 02-202
ACCIDENT SOURCE TERMS FOR LIGHT-WATER NUCLEAR POWER PLANTS:
HIGH BURNUP AND MIXED OXIDE FUELS
Draft Report: June 2002 Final Report: November 2002
Energy Research, Inc. -P.O. Box 2034
Rockville, Maryland 20847-2034
Work Performed Under the Auspices of the United States Nuclear Regulatory Commission
Office of Nuclear Regulatory Research Washington, D.C. 20555
ERL/NRC 02-202
ACCIDENT SOURCE TERMS FOR LIGHT-WATER NUCLEAR POWER PLANTS:
HIGH BURNUP AND MIXED OXIDE FUELS
Draft Report: June 2002 Final Report: November 2002
Energy Research, Inc. P. 0. Box 2034
Rockville, Maryland 20847-2034
Work performed under the auspices of
United States Nuclear Regulatory Commission Washington, D.C.
Under Contract Number NRC-04-97-040
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I
PREFACE
This report has been prepared by Energy Research, Inc. based on work performed by a
panel of experts organized by the United States Nuclear Regulatory Commission, Office
of Nuclear Regulatory Research, to develop recommendations for changes, if necessary,
to the revised source term as published inlNUREG-1465, for application to high burnup
and mixed oxide fuels.
Dr. Brent Boyack of Los Alamos National Laboratory served as the panel facilitator, and
Energy Research, Inc. has been responsible for the preparation of the final report.
Individual contributors to this report include:
Executive Summary M. Khatib-Rahbar
Section 1 M. Khatib-Rahbar
Section 2 H. Nourbakhsh
Section 3 B. Boyack
Section 4 M. Khatib-Rahbar
Substantial technical input was provided to the panel, by Mr. A. Hidaka of the Japan
Atomic Energy Research Institute (JAERI), and Mr. J. Evrard of the Institut de
Radioprotection et de Sfiret6 Nuclkaire (IRSN).
This work has been performed under the auspices of the United States Nuclear
Regulatory Commission, Office of Nuclear Regulatory Research, under contract number
NRC-04-97-040. Mr. Jason Schaperow, the NRC Project Manager, provided considerable
input to the conduct of the panel activities and the preparation of this report.
M. Khatib-Rahbar Energy Research, Inc.
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EXECUTIVE SUMMARY
E.1 - Introduction
The reactor site criteria of 10 CFR Part 100 require that an accidental fission product
release resulting from "substantial meltdown" of the core into -the containment be
postulated to occur and that its potential radiological consequences be evaluated
assuming that the containment remains intact but leaks at its maximum allowable leak
rate. Radioactive material escaping from the containment is often referred to as the
"radiological release to the environment." The radiological release is obtained from the
containment leak rate and knowledge "of the airborne radioactive inventory in the
containment atmosphere. The radioactive -inventory within containment is referred to as
the "in-containment accident source term."
For currently licensed nuclear power. plants, the characteristics of the fission product
release from the core into the containment are set forth in Regulatory Guides 1.3 and 1.4
and have been derived from the 1962 report, TID-14844.
Using the results of research on severe accidents and fission product releases since the
publication of TID-14844, NUREG-1465 proposed revised source terms to the
containment for Light-Water Reactors (LWRs), which are based on more realistic
assumptions as related to release duration, release quantity, -fission product aerosol
retention, and chemical forms, to replace the TID-14844 based source term in licensing
applications. Regulatory Guide 1.183 .("Altemative Radiological'-Source Terms for
Evaluating Design Basis Accidents at Nuclear Reactors") was developed by NRC to
support the final rule that amended 10 CFR-Part 21, 50, and 54. The revised source term
as proposed in NUREG-1465 is primarily-based on experiments and analytic studies
applicable to low bumup (i.e., less than 40 GWd/t) U0 2 fuel.
Since the publication of NUREG-1465; ,additional research has been completed,
including experimental and analytic studies in France and Japan. These experiments also
include the effects of fuel bumup (up to 60 GWd/t) for U0 2 and fuel composition (i.e.,
mixed oxide fuels).
The objective of this report is to assess the-applicability of NUREG-1465, and if possible,
to define a revised accident source term forregulatory application to reactors using high
bumup (i.e.,' bumup up to 75 GWd/MTU) low enriched uranium (LEU) fuel and to
reactors using mixed oxide (MOX) fuel. Those aspects of the source term as proposed in
NUREG-1465 that are potentially impacted by the use of high bum-up or MOX fuels are
addressed, including chemical and physical forms, release timing, and release magnitude
for a"low pressure accident sequence. Otherwise, the recommendations of NUREG-1465
are expected to -be applicable. Specific recommendations on the need for additional
research tohelp establish appropriate source terms for high bumup -and MOX fuels
applications are also provided.
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E.2 Approach
The approach used in this effort is based on reconstitution of the source term panel that developed the source term uncertainty distributions for the NUREG-1 150 study, which also served as the technical basis for NUREG-1465; and by considering (a) the data and insight that have been generated since NUREG-1465 was published, and (b) the physical phenomena that affect fission product release and transport mechanisms for high bumup and MOX fuels.
The panel did not have the benefit of the results of accident sequence analyses using accident analysis models validated by comparison to pertinent test results involving high bumup or MOX fuels. In addition, in many areas, the panel identified gaps in experimental data to support specific panel recommendations. Therefore, the members of the panel have attempted to qualitatively integrate the results of recent tests to predict fission product releases during accidents at nuclear power plants. They have extrapolated phenomenology of core degradation based on existing studies for conventional bumup of LEU fuels to anticipate fission product releases from fuel at bumup levels in excess of about 60 GWd/t. The panel members have also extrapolated the behavior of LEU fuels with conventional Zircaloy cladding to estimate the behavior of mixed oxide fuel with zirconium-niobium alloy (M5) cladding.
E.3 Insights and Recommendations
Consistent with NUREG-1465, the source term applicability panel assumed that the proposed release fractions are intended to be representative or typical, rather than conservative or bounding values, of those associated with a low-pressure core-melt accident, although each panel member provided his own release estimates, and in some cases these individual estimates may be considered as conservative rather than typical. Therefore, the release fractions into the containment as recommended herein are not expected to bound all potential severe accident scenarios, or to represent any single scenario/sequence.
In formulating the proposed changes to the NUREG-1465 source term, for application to reactor accident analyses for high bumup and MOX fuels, attention was also given to the changes in our understanding of LEU fuel fission product release that have come about since issuance of NUREG-1465 because of major experimental investigations of fission product behavior under reactor accident conditions, including the Phebus-FP and the VERCORS experiments.
The panel assessment was based on a maximum assembly burnup of about 75 GWd/t and a core average bumup of about 50 GWd/t. The assessment also was based on Zirlo cladding for a PWR and Zircaloy cladding for a BWR. In addition, the assessment of fission product release fractions was based on a low pressure scenario; this minimizes retention and is consistent with the approach taken in developing the NUREG-1465 source term.
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The results of the panel assessment for high burnup fuel were that the physical and
chemical forms of the NUREG-1465 source term are expected to be applicable and only
small changes in the release-phase durations and release fractions are -expected.
However, the panel identified some issues with the NUREG-1465 source term based on
recent tests. These issues are independent of fuel burnup. One issue-is the potential for
enhanced tellurium release, which is discussed further below. Another issue is the
continued uncertainty in the releases of noble metals, cerium, and lanthanum groups.
Also, recent data suggests subdividing noble metals, cerium, and lanthanum groups into
additional groups. -The panel also discussed the related issues of BWR power uprates and
BWR fuel design.
With regard to tellurium, the NUREG-1465 source term specifies for the early in-vessel
release of tellurium a release fraction of 0.05. This is supported by Oak Ridge National
Laboratory tests indicating that the tellurium gets sequestered in the tin in the Zircaloy
cladding and it is not released until a high fraction of the cladding is oxidized." However,
more recent French tests (i.e., VERCORS, PHEBUS-FP) indicate that the tellurium
release could be similar to that of iodine release (e.g., about 0.3). For PWRs, this was a
contentious issue among the panel members. However, for BWRs, the panel members
specified release fractions similar to the NUREG-1465 source term. This is because the
BWR Zircaloy fuel channels tend to limit cladding oxidation.
One source term issue related to high burnup is BWR power uprates. With regard to this
issue, one expert saw no basis for a significant effect on the fission product release.
However, another expert stated that the flux-profile flattening associated with power
uprates could increase the fission product release rate for the outer assemblies. 'Another
source term issue related to high burnup involves BWR fuel design. NUREG-1465
specifies a different source term for a BWR itian for a PWR. However, the characteristics
of more recent BWR fuel rod designs are closer to those of PWR fuel rods (e.g., similar
pellet diameter, similar cladding thickness, etc.). The panel indicated tliat similar fuel rod
designs would tend to result in similar source terms.
The assessment of the applicability of the NUREG-1465 source term for MOX fuel was
based on using MOX fuel in approximately half of the core. The assessment also was
based on a typical MOX assembly burnup of about 42 GWd/t and M5 cladding., As with
.high bumup fuel, the assessment of fission product release fractions was based on a low
pressure scenario.
The results of the panel assessment for MOX fuel'were that the physical and chemical
forms of the NUREG-1465 source term are expected to be applicable and only small
-changes in the release-phase durations' and release fractions for noble gases, iodine and
cesium are expected. The panel identified the same tellurium issue as With high bumup
fuel.: One difference from the assessment for high burnup fuel was that for MOX fuel,
some of the experts did not recommend release fractions for the following groups because
of the lack of test data: barium/strontium, noble metals, cerium, and lanthanum. The only
MOX data that was available to the panel was a VERCORS test result for cesium with an
arbitrary scale on the axis representing the release magnitude.
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The limitations of the analysis and the available data make additional research to confirm the panel's estimates important. Therefore, in response to a request from NRC, the panel members provided specific recommendations for research to confirm the proposed changes to the revised source term. The high priority recommendations for research, include:
1. Acquire any available database on fission product release rates from high burnup and MOX fuels, in order help the panel to update the panel recommendations included herein. This data will also help to parameterize the available fission product release models in the systems codes used to analyze reactor accidents.
2. Validation of accident analysis tools (i.e., MELCOR, VICTORIA) by comparison of predictions with results of major source term tests (e.g., PHEBUS-FP, VEGA and VERCORS with fuel of various burnup levels and MOX fuel) is needed. These comparisons that will lead to improvements and ultimately validation of the computer codes are essential steps before analyses of significant accident sequences using accident analysis tools.
3. Experimental investigation of in-vessel core degradation following vessel failure is important in verifying the impact of air-ingression on producing radically different source term (e.g., verification of the Canadian tests showing a nearly complete release of radioactive ruthenium in air). This is also an important issue for the assessment of spent fuel pool accidents, fuel transportation and dry cask storage of fuel.
4. Tests of core degradation with MOX fuel in order to assess damage progression behavior, including an assessment of the oxygen potential of MOX fuel in order to develop a better understanding of the chemical forms and volatility of various released constituents. These tests need to be performed with fuel rod bundles to investigate the fuel liquefaction, fuel relocation and fission product releases during the degradation process.
5. Applicability of MOX data and models needs to be established. In particular, the differences, if any, in the fuel degradation behavior between the MOX fuel that has been prepared with reactor-grade plutonium dioxide to the fuel that has been prepared from weapons-grade plutonium dioxide (of primary interest in the United States), need to be assessed analytically and/or experimentally.
6. Fuel burnup is expected to have an impact on the fuel melting point and fuel liquefaction process. The interaction of melting cladding with the fuel can be affected by the development of a restructured 'rim' region and by the formation of a significant oxide layer on the inner surface of the cladding. Perhaps of more significance is the possibility that the degradation of high burnup fuel will involve 'fuel foaming' rather than fuel candling as observed with fuel at lower bumup levels. This could change the core degradation process and consequently the release of fission products from the degrading fuel in qualitative ways that cannot be
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appreciated by simply extrapolating the results of tests with lower burnup fuel.
Therefore, experimental investigation of fuel at high bumup, and with cladding
material that include tin and niobium (Zirlo) or zirconium-niobium alloys (M5), are
essential in confirming the radiological release characteristics (e.g., effects of tin in
M5 cladding on tellurium release) of fuels at high burnup and with new cladding material.
7. Revaporization is an important element of the revised source term as documented in
NUREG-1465 and the present report. The actual magnitude of the revaporization
component depends on the vapor pressures of the deposited radionuclides and these
vapor pressures depend on the chemical form of the deposited radionuclide.
Unfortunately, there is a limited understanding of the chemical forms of the
deposited radionuclides. Consequently, empirical data are required on the
vaporization of deposited radionuclides for comparison with predictions of models
of the revaporization process.
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TABLE OF CONTENTS
PREFACE ............................................................................................................................ i
EXECUTIVE SUMMARY ............................................................................................... 1.°
E.1 Introduction .................................... 1:...---............................................................ ,11
E.2 Approach ..................................................................................................... iv
E.3 Insights and Recommendations ................................ . v
ACRONYM S .................................................................................................................... xv
1. I TROD CTI N ................. -: ............. -................................. ........................... 1
1. INTRODUCTION............................... ........ I
1.1 Background ....................................................................................................... 1
1.2 Objectives .................................................................................................... 3
1.3 Approach ........................................................................................................... 3
2. BASIS FOR REVISED (NUREG-1465) SOURCE TERM ................................. 5
2.1 Progression of Severe Accident Sequences and Release Phases .................. 5
2.2 Accidents Considered .................................................................................. 7
2.3 Fission Product Composition ....................................................................... 8
2.4 Fission Product M agnitude ........................................................................... 9
2.5 Timing of Release Phases ........................................................................... 11
2.6 Iodine Chemical Form ................................................................................ 12
3. PANEL RECOMMENDATIONS AND BASIS FOR RECOMMENDATIONS
FOR HIGH BURNUP AND M OX FUELS ....................................................... 15
3.1 Panel Organization and Elicitation Process ................................................ 15
3.2 PW R Accident Source Term ....................................................................... 18
3.2.1 PW R Accident Sequence ................................................................ 18
3.2.2 PW R Fuel Characteristics .............................................................. 18
3.2.3 PW R Accident Source Term .......................................................... 18
3.3 BWR Accident Source Term ..................................................................... 19
3.3.1 BW R Accident Sequence ................................................................ 19
3.3.2 BW R Fuel Characteristics .............................................................. 19
3.3.3 BW R Accident Source Term ......................................................... 33
3.4 MOX Accident Source Term for Light-Water Nuclear Power Plants ...... 35
3.4.1 M OX Accident Sequence .............................................................. 36
3.4.2 M OX Fuel Characteristics ............................................................... 36
3.4.3 M OX Accident Source Term .......................................................... 37
4. INSIGHTS AND RECOMMENDATIONS ....................................................... 51
4.1 High Burnup Fuel ...................................................................................... 51
4.1.1 P. Rs .............................................................................................. 52
4.1.2 BW Rs .............................................................................................. 53
4.2 MOX Fuels ................................................................................................... 54
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4.3 Panel Recommendations on Research Needs to Confirm Changes to the Revised Source Term ................................................................................. 55
5. REFEREN CES ..................................................................................................... 59
APPENDIX A: SOURCE TERM PANEL MEMBERS ............................................ 63 A .1 Panel M em bers ............................................................................................. 65 A .2 Facilitator .................................................................................................... 65 A.3 Vitae of Panel Members ............................................................................. 65
APPENDIX B: PANEL RECOMMENDATIONS ON RESEARCH NEEDS TO CONFIRM CHANGES TO THE REVISED ACCIDENT SOURCE T ER M ................................................................................................. 69
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LIST OF TABLES
Table 2.1 Revised Radionuclide Groups ................................ 8
Table 2.2 BWR Core Inventory Release Fractions for the Revised (NUREG-1465) Accident Source Term ..................................... 9
Table 2.3 PWR Core Inventory Release Fractions for the Revised (NUREG-1465)
Accident Source Term ............................................................................... 9
Table 2.4 Timing of Release Phases ...................................................................... 11
Table 3.1 PWR Releases Into Containment (High Burnup Fuel) .......................... 20
Table 3.2 Rationales for Duration Entries in Table 3.1 ........................................... 22
Table 3.3 Rationales for Noble Gases Entries in Table 3.1 .................................... 23
L Table 3.4 Rationales for Halogen Entries in Table 3.1 .......................................... 25
L Table 3.5 Rationales for Alkali Metals Entries in Table 3.1 .................................. 26
Table 3.6 Rationales for Tellurium Group Entries in Table 3.11 ............................ 27
Table 3.7 Rationales for Barium and Strontium Entries in Table 3.1 .................... 29
Table 3.8 Rationales for Noble Metals Entries in Table 3.1 .................................... 30
Table 3.9 Rationales for Cerium Group Entries in Table 3.1 .................................. 31
Table 3.10 Rationales for Lanthanides Entries in Table 3.1 .......................................... 32
Table 3.11 BWR Releases Into Containment (High Burnup Fuel) .......................... 34
Table 3.12 MOX Releases Into Containment4 ............................. . . .. .. . . . . . . . . . . . . . . . . . . . . . . 38
Table 3.13 Rationales for Duration Entries in Table 3.121 ....................................... 39
Table 3.14 Rationales for Noble Gases Entries in Table 3.12 .................................. 40
Table 3.15 Rationales for Halogens Entries in Table 3.12 ...................................... 41
L Table 3.16 Rationales for Alkali Metals Entries in Table 3.12 ................. 43
Table 3.17 Rationales for Tellurium Group Entries in Table 3.12 ........................... 44
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Rationales for Barium and Strontium Entres in Table 3.12 .................. 45
Rationales for Noble Metals Entries in Table 3.12 .............................. 46
Rationales for Cerium Group Entries in Table 3.12 ................................ 48
Rationales for Lanthanides Entries in Table 3.12 .................................... 49
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Table 3.18
Table 3.19
Table 3.20
Table 3.21
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LIST OF FIGURES
Figure 2.1 Progression of Severe Accident Sequences and Associated Release Phases .... 6
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ACRONYMS
BWR Boiling Water Reactor FSAR Final Safety Analysis Report HPME High Pressure Melt Ejection IRSN Institut de Radioprotection et de Sfiret6 Nucl~aire JAERI Japan Atomic Energy Research Institute LANL Los Alamos National Laboratory LEU Low Enriched Uranium LOCA Loss of Coolant Accident LWR Light Water Reactor MOX Mixed Oxide NRC Nuclear Regulatory Commission PWR Pressurized Water Reactor RCS Reactor Coolant System SE Steam Explosion SNL Sandia National Laboratories STCP Source Term Code Package TR Total Release
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1. INTRODUCTION
1.1 Background
The history of the use of postulated accidental releases of radioactive material in the
regulatory practices'of the U.S. Nuclear Regulatory Commission (NRC) is summarized in
Reference [1].
The NRC's reactor site criteria of 10 CFR Part 100 [2] require; for licensing purposes,
that' an accidental fission product releaie'resulting from "substantial meltdown" of the
core into the containment be postulated to occur and that its potential radiological
consequences be evaluated assuming that the containment remains intact but leaks at its
maximum allowable leak rate. Radi6activ'e material escaping from the containment is
often referred to as the "radiological relea~se to the environment." The radiological release
is obtained from the containment leak rite and a knowledge of the airborne radioactive
inventory in the containment atmosphere. The radioactive inventory within containment
is referred to as the "in-containment accident ýource term."
The expression "in-containment accident -source term," as used in this document is
identical to that of Reference [1] which is rdefined as the radioactive material composition
and magnitude, as well as the chemical anid physical properties of the material within the
containment that are available for leakage'from the reactor to the environment. It is noted
that the "in-containment accident source - term"- is normally a function of time and
involves consideration of both fission' products being released from the core into the
containment, and the fission product removaýl by -various mechanisms including natural
processes and operation of engineered systems (e.g., containment sprays).
For currently licensed plants, the characteiistics 'of the fission product release from the
core into the containment are set forth in Regulatory Guides 1.3 [3] and 1.4 [4] and have
been'derived from the 1962 report, TID-14844 [5]. This release consists of:
* 100% of the core inventory of noble gases
* 50% of the core inventory of iddine (half of which are assumed to deposit on
interior surfaces) * 1% of the remaining solid fission products
Note that the latter was removed from c6nsideration in Regulatory Guides 1.3 and 1.4.
However, the 1% of the solid fission products is considered in certain areas such as
equipment qualification [1].
As stated in Reference [1], Regulatory Guides 1.3 and 1.4 specify that the iodine
chemical form is assumed to be predominantly (91%) in elemental (12) form, with 5%
assumed to be particulate iodine and the remaining 4% is assumed to be in organic form
(CH 3I, etc.). In addition, releases are assumed to occur instantaneously into the
containment, following a postulated design basis accident.
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Using the results of research on severe accidents and fission product releases since the publication of TID-14844, NUREG-1465 [1] proposed revised source terms to the containment for Light-Water Reactors (LWRs), which are based on more realistic assumptions as related to release duration, release quantity, fission product aerosol retention, and chemical forms, to replace the TID-14844 based source term in licensing applications. Regulatory Guide 1.183 ("Alternative Radiological Source Terms for Evaluating Design Basis Accidents at Nuclear Reactors") was developed by NRC to support the final rule that amended 10 CFR Part 21, 50, and 54. The revised source term as proposed in NUREG-1465 [1] is primarily based on experiments and analytic studies applicable to low burnup (i.e., less than 40 GWd/t) U0 2 fuel. Note that the use of the revised source term (NUREG-1465) has been voluntary by the licensees.
Additional research has been completed since the publication of NUREG-1465. This includes experimental and analytic studies in France [6-8] and Japan [9], and studies performed by others [10-12]. The French' experimental programs [6] include the fission product release HEVA VERCORS experiments, the fission product vapor deposition condensation DEVAP studies, the aerosol behavior TUBA, TRANSAT, PITEAS and FUCHSIA experiments, the CARAIDAS spray experiments, the small scale EPICUR, CAIMAN, and CHIP experiments dealing with iodine, and the Phebus-FP integral experiments. In addition, data have been collected in France through measurements to determine the gap inventory of the spent fuel rods from reactors at different bumup levels (up to 60 GWd/t) for U0 2 and mixed oxide fuels. Furthermore, in-pile FLASH experiments [8] have been performed to measure the fission product release from a fuel rod under Loss Of Coolant Accident (LOCA) conditions, including one experiment which involved high bum-up fuel (i.e., 50 GWd/t).
The VEGA experimental program [9] at the Japan Atomic Energy Research Institute (JAER[) is focusing on investigation of fission product releases from irradiated PWR and BWR fuel with fuel burnup ranging from 26 to about 61 GWd/t. Tests are also planned at JAERI that will include the spent MOX fuel from several European power plants with bumup levels reaching 80 GWd/t.
The regulatory applications of the revised source term (gap and in-vessel release phases) as used for LOCA design basis analyses include:
"* Assessment of individual dose at the Exclusion Area Boundary, at the Low Population Zone distance, and in the control room.
" Containment isolation valve closure time (start time of gap release).
"* Integrated dose used to qualify equipment in containment.
"* Post accident shielding, sampling, and access.
'The results of the French fission products release expenmental research are not available to U. S. Nuclear Regulatory Commission.
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In addition, the revised source term may be used for other regulatory applications (e.g.,
NUREG-1738 [13]).
1.2 Objectives
The primary objective of this report is toassess the applicability of NUREG-1465, and if
possible, to define a revised accident source term for regulatory application to reactors
using high bumup (i.e., bumup up to 75 GWd/MTU) low enriched uranium (LEU) fuel
and to reactors using mixed oxide (MOX) fuel. Those aspects of the source term as
proposed in NUREG-1465 that are potentially impacted by the use of high bum-up or
MOX fuels will be addressed. The specific aspects addressed are chemical and physical
forms, release timing, and release magnitude for a low-pressure accident sequence.
Otherwise, the recommendations of NUREG-1465 are expected to be applicable.
1.3 Approach
The approach used in this effort is based on reconstitution of the source term panel that
developed the source term uncertainty distributions for the NUREG-1150 study, which
also served as the technical basis for NUREG-1465 [1]; and by considering (a) the data
and insight that have been generated since NUREG-1465 was published, and (b) the
physical phenomena that affect fission product release and transport mechanisms for high
bumup and MOX fuels.
The panel was requested to provide specific recommendations for changes, if necessary,
to the revised source term as published in NUIREG-1465 [1], for high bumup and MOX
fuels.
The panel meetings and deliberations were conducted during three meetings held at the
Nuclear Regulatory Commission (NRC) Headquarters in Rockville, Maryland. All panel
deliberations were transcribed. The list of panel members, and short biographies of each
of the panel members are presented in Appendix A.
The panel was also requested to provide specific recommendations on the need for
research to help establish appropriate source terms for high bumup and MOX fuels
applications. Each letter from the panel members on the specific research
recommendations is included in Appendix B.
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2. BASIS FOR REVISED (NUREG-1465) SOURCE TERM
In 1995, the U.S. Nuclear Regulatory Commission published NUREG-1465, "Accident
Source Terms for Light-Water Nuclear Power Plants" [1], which defined a revised
accident source term for regulatory application. NUREG-1465 utilized current technical
knowledge and understanding of LWR severe accident phenomeiology to present, for
regulatory purposes, a more realistic portrayal of the radionuclides present in the
containment from a postulated severe accident. NUREG-1465 presents a representative
accident source term for a Boiling Water Reactor (BWR) and for a Pressurized Water
Reactor (PWR). These source terms ari€characterized by the composition and magnitude
of fission product release into containment, the'timing of the release into containment,
and the physical and chemical forms in containment.
This chapter provides a summary of the technical basis for the NUREG -1465 accident
source term. A brief qualitative discussion of the phenomenology of fission product
release and transport behavior during the progression of severe accidents is presented and
the technical basis for characterizing the revised accident source term parameters
(composition, magnitude, timing and physical and chemical forms) is described.
2.1 Progression of Severe Accident Sequences and Release Phases
Radiological releases into containment under severe accident conditions can be generally
categorized -in terms of phenomenological phases associated with the degree of core
damage and degradation, reactor pressure vessel integrity, and, -as applicable, attack upon
concrete below the reactor cavity by molten core materials. The general phases, or
progression, of a severe LWR accident are shown in Figure 2.1.
Initially there is a release of coolant activity associated with a break'or leak in the reactor
coolant system (RCS). The radiological releases during the coolant activity release phase
are- negligible in comparison to the releases during the subsequent release phases.
Assuming that the coolant loss cannot be accommodated by the reactor coolant makeup
systems, or the emergency core cooling systems, fuel cladding failure would occur.
Upon failure of the cladding, a small quantity of fission products that resides in the gap
between fuel pellets and the fuel cladding, would be released. This release, which is
termed the gap release, would consist mostly of the volatile nuclides, particularly noble
gases, iodine, and cesium.
As the accident progresses, core degradation begins, resulting in loss of fuel geometry
accompanied by melting and relocation- of core materials to the bottom of the 'reactor
pressure vessel. Due to temperature -variation within the core (impacted bý' factor such as
power density, fuel loading pattern, etc.)'the core degradation and subsequent melting and
relocation of the core would occur on a region-by-region basis (heterogeneously). Thus,
the total release of any radionuclide 'would'occur over a period of time. During this
period, the early in-vessel phase, significant quantities of the volatile nuclides in the'core
inventory as well as small fractions of the less volatile nuclides -are released into
containment. The fission products and other materials, which are released from the fuel,
ERIINRC 02-202Energy Research, Inc. 5
I Core -Concrete &-Vess Release I Intertion Release Due to I A
I H I-IPME / -
-- -I --- - Release Due to
•. Ex-Vessel SE _ __
( Late Revolatilization [te In-Vessel - roth, Cý )17 Release )
Figure 2.1 Progression of Severe Accident Sequences and Associated Release Phases
are likely to be transported through the various regions of the RCS before reaching the containment. As they move through the RCS, fission products may be retained as a result of various types of interactions. The extent of this retention depends on the accident scenario (thermal hydraulic conditions along the flow path, RCS breach or leakage location, etc.). The released fission product gases could absorb or condense onto aerosols and RCS surfaces, or react chemically with other species in the RCS atmosphere or with RCS surfaces. The amounts of fission products released into containment during the early in-vessel release phase are influenced by the residence time of the radioactive material within the RCS during core degradation. High-pressure sequences result in long residence times and significant retention of fission products within the RCS, while lowpressure sequences result in relatively short residence times and less retention within the RCS and consequently higher releases into containment.
If the bottom head of the reactor pressure vessel fails, two additional release phases (exvessel and late in-vessel) may occur. Following the bottom head failure, the molten core debris will be released from the reactor pressure vessel to the containment. Contact of molten core debris with the concrete structural materials of the cavity/pedestal below the reactor could lead to core-concrete interactions. As a result of these interactions, the
Energy Research, Inc. 6 ERI/NRC 02-202
.remaining quantities of the volatile radionuclides not already released during the in-vessel
-phase as. well as lesser quantities of non-volatile radionuclides are released into the
,containment atmosphere. Core-concrete interactions liberate copious amounts of concrete
decomposition gas products. These gases would, in turn, sparge some of the less volatile
nuclides, such as barium and strontium, and small fractions of the refractory nuclides'into
the containment atmosphere. Large quantities of non-radionuclide aerosols may'also be
released as a result of core-concrete interactions. The presence of water in the' ieactor
cavity/pedestal overlaying any core debris can significantly reduce the ex-vessel releases
• (both radioactive and non radioactive) into the containment,-e'ither by" co6ling the core
debris, or at least, by scrubbing the releases and retaining a large fraction in the water.
-Two other phenomena that affect the ex-vessel release of fissi6n products into
containment could also occur. The first of these is referred to as "high pressure melt
ejection" (HPME). If the RCS is at high pressure at the time of failure of the bottom head
of the reactor pressure vessel, quantities of molten core materials could be ejected into the
containment at high velocities. In addition to -a potentially rapid'rise in containment
temperature, a significant amount of radioactive material could also be added to the
containment atmosphere, primarily in' the form of aerosols. The extent of HIPME is
reduced at low RCS pressures. A second phenomena that could affect the'release of
fission products into containment is a possible steam explosion (SE) as a result of
interactions between molten core debris and water. This could lead to fine fragrmentation
of some portion of the molten core debris with an increase in the amount of airborne
fission products. While small-scale steam explosions may occur, they will not result in
significant increases in the airborne activity already within the containment. Large-scale
,steam explosions on the other hand, could result in significant increases in airborne
activity temporarily, but are much less likely to occur. In any event, releases of
particulates or vapors during steam explosions will also be accompanied by, large
amounts of water droplets, which would tend to quickly sweep released materials from
the atmosphere.
Following the failure of the bottom head of the reactor pressure vessel, home of the
volatile nuclides may be released into containment as a result of re-volatilization of the
mantefial, which had deposited on RCS structures during the in-vessel -phase, -or
volatilization of material remaining Mi the 'reactor pressure vessel after vessel breach.
This late in-vessel release phase proceeds-simultaneously with the occurrence'of the ex
vessel phase. However, the late in-vessel releases have generally a longer duration than
that of the ex-vessel releases.
2.2 Accidents Considered
In order to determine revised accident soiirce terms for regulatory purposes, the-NRC
sponsored studies [14-16] that analyzed the timing, magnitude, and duration of fission
product releases into containment. In addition, an examinatioin -and assessment of0the
che riical for-m of iodine likely to be found ýwithin containment as -a result of a severe
accident was also carried out [17].
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A range of severe accidents that were previously analyzed for LWR plants was examined. Evaluation of a range of severe accident sequences was based upon work done in support of NUREG-1150 [18] study. The sequences studied progressed to a complete core-melt, involving failure of the reactor pressure vessel and including core-concrete interactions. It should be noted that these sequence calculations were limited to cores with low burnup fuel (i.e., burnup up to 39 GWd/MTU) and without any MOX fuel2.
The revised source terms presented in NUREG-1465 were intended to be representative or typical, rather than conservative or bounding values, of those associated with a low pressure core melt accident, except for the onset of the release of gap activity, which was chosen conservatively. The release fractions for the revised source term were not intended to envelop all potential severe accident sequences, or to rigorously represent any single sequence.
2.3 Fission Product Composition
WASH-1400 [19] examined the spectrum of fission products and grouped 54 radionuclides into 7 major groups on the basis of similarity in chemical behavior. The effort associated with the Source Term Code Package (STCP) [20] further analyzed these groupings and expanded the 7 fission products groups into 9 groups.
Both the results of the STCP analyses and the uncertainty analysis reported in NUREG/CR-5747 [15] indicated minor differences between Ba and Sr releases. Hence a revised grouping of radionuclides was developed that groups Ba and Sr together. A study of relative importance to offsite health consequences of the radioactive elements in a nuclear power reactor core, reported in NUREG/CR-4467 [21 ], found that other elements such as curium could be important for radiological consequences if released in sufficiently large quantities. For this reason, curium (Cm), americium (Am), and cobalt (Co) were also added to radionuclide elements. The revised radionuclide groups used in NUJREG-1465 including the elements comprising each group are shown in Table 2.1.
Table 2.1 Revised Radionuclide Groups
GrouD Elements in Grout Noble Gases Xe, Kr Halogens L Br Alkali Metals Cs, Rb Tellurium Group Te, Sb, Se Barium, Strontium Ba, Sr
Noble Metals Ru, Rh, Pd, Mo, Tc, Co Lanthanides La, Zr, Nd, Eu, Nb, Pm, Pr, Sm, Y, Cm, Am
Cerium Group Ce, Pu, Np
2 Note that computer calculations have not been performed as part of the present effort because the ability
of the current accident analysis codes to properly predict the degradation of high bumup and MOX fuels is in doubt.
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2.4 Fission Product Magnitude
The core inventory release fractions for the, NUREG-1465 accident source term, by
radionuclide groups, are listed in Table 2.2 for BWRs and Table 2.3 for PWRs. It should
be noted that the late in-vessel release fractions for halogens and alkali metals for BWtRs
listed in Table 2.2 are different than thidie'rep6rted erroneously in the final version of
NUREG-1465 [1].
BWR Core Inventory Release Fractions Accident Source Term
Gap Release Early In-Vessel
for the Revised
Ex-Vessel
(NUREG-1465)
Late In-Vessel
Noble Gases 0.05 0.95 - 0 0
Halogens 0.05 0.25 0.30 0.1
Alkali Metals 0.05 0.20- 0.35 -0.1
Tellurium group 0 0:05- 0.25 0.005
Barium, Strontium 0 0.02 0.1 0
Noble Metals 0 0.0025 0.0025 0
Lanthanides 0. 0.0005 0.005 0
Cerium group 0 0.0002 0.005 0
Table 2.3 PWR -Core Inventory Release Fractions for the Revised (NUREG-1465)
Accident Source Term
Group Gap Release Early Iri-Vessel Ex-Vessel Late In-Vessel
Noble Gases 0.05 0.95 - 0 0
Halogens 0.05 0.35 0.25 0.1
Alkali Metals "0.05 '0.25 0.35 0.1
Tellurium group
.Barium, Strontium
0 0.05 0.25+ t I
0 6.02______________________ t + - *1-
Noble Metals 0 0.0025
0.1
0.0025____________ 4 1
Lanthanides 0 0.0005 0.005_ _ _ _ _ _ _ _ - i I T
0.0002.. 0.005I_ _ _ __ _ _ I_ _ _ _ _
0.005
0
0
0
0
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Table 2.2
Group
PCernum oQrAnl
Based on WASH-1400 [19], the inventory of volatile fission products, residing in the gap
betweefn-the fuel- and the cladding is _n6 greater than 3 percent except for cesium, which
9
v•I••AA
was estimated to be 5 percent. NUREG/CR-4881 [14] reported a comparison of more recently available estimates and observations indicating that releases of the dominant fission product groups were generally below the values reported in WASH-1400. NUREG-1465 recognized that for degraded core or core-melt accidents, the gap release phase may overlap to some degree with the early in-vessel release phase. Therefore, the release magnitude was taken as an initial release of 3 percent of the volatile fission products (noble gases, iodine, and cesium), which are in the gap between the fuel pellet and the cladding, plus an additional release of 2 percent over the duration of the gap release phase.
The early in-vessel, ex-vessel and late in-vessel release fractions for the revised accident source terms were derived from the simplification of NUREG-1 150 [18] source terms documented in NUREG/CR-5747 [15]. NUREG/CR-5747 [15] utilized the current technical knowledge and understanding of the source term phenomenology to develop simplified formulation for realistic estimates of source term release into containment in terms of timing, nuclide types and quantities. Source terms parameters were quantified based on the detailed examination of available information, including results of the integrated Source Term Code Package (STCP) computer codes calculations and the insights from the NUREG-1 150 expert elicitation on source terms issues [22]. Uncertainty analyses were also performed for releases into containment by utilizing the probability distributions for source term parameters used in NUREG- 1150 study.
The early in-vessel release fractions presented in Tables 2.2 and 2.3, except for the lowvolatile nuclides, are generally the mean values of the uncertainty distributions for a typical low-pressure core-melt accident scenario documented in NUREG/CR-5747 [15]. The range of release estimates for the volatile nuclides, such as noble gases, iodine, cesium, and to some extent tellurium, spans about one order of magnitude. Therefore, it was concluded that for this group of nuclides, use of the mean value is a reasonable estimate of the release fraction. In contrast, the range of release estimates for the lowvolatile nuclides, such as barium, strontium, ruthenium, cerium and lanthanum, spans about four to six orders of magnitude. For the latter group of nuclides, the mean is controlled by the upper tail of the distribution, and the details of the whole distribution may be more indicative of the uncertainty than the "bottom line" results such as a mean value. Hence, in the final NUREG-1465 report, the 75th percentile value was selected for the low volatile nuclides on the basis that it bounds most of the range of values, without undue influence by the upper tail of the distribution. It should be noted that, in the final NUREG-1465 report, the in-vessel release fraction for the tellurium was reduced from the draft version values of 0.11 (BWR) and 0.15 (PWR) to 0.05 in response to comments that tellurium will be retained via reaction with the Zircaloy cladding, with major releases occurring only on extensive oxidation of the clad.
The ex-vessel release fractions for the revised accident source terms are generally the mean values of the uncertainty distributions for releases associated with core-concrete interactions documented in NUREG/CR-5747 [15]. The late in-vessel releases due to heat up and degradation of the residual fuels following the vessel failure were not considered explicitly. However, it was assumed that the entire core participates in coreconcrete interactions and therefore the volatile species (i.e., iodine and cesium) remaining
Energy Research, Inc. 10 ERI/NRC 02-202
in the reactor pressure V69§el at the reactor vessel breach were assumed to be released
during the ei-vessel release phase. It should be noted that, in the final NUREG-1465
report, the ex-vessel releases for tellurium-and the low volatile nuclides were reduced as a
result of comments received.
The late in-vessel release fractions piesehted'in Tables 2.2 and 2.3 are also generally the
mean values of the uncertainty distributions for a typical low-pressure core-melt accident
scenario documented in NUREG/CR-5747 [15]. These releases are associated with the
revaporization of radionuclides retained in the RCS and their subsequent release into the
containment after the vessel failure.
2.5 Timing of Release Phases
Table 2.4 shows the onset and duration for each release phase of the revised accident
source terms for BWRs and PWRs. The specified onset is the time following the
initiation of accident (i.e., time=0). It should be also noted that the rate of release' of
fission products into the containment is assumed to be constant during the time duration
,shown.
Table 2.4 Timing of Release Phases
BWRs PWRs Release Phiase
Onset Duration Onset Duration
Gap Release 30 sec 0.5 hr 10-30 sec 0.5 hr
Early In-Vessel 0.5hr 1.5 hr 0.5 hr 1.3 hr
Ex-Vessel 2. ir 3 hr 1.8 hr 2 hr
Late In-Vessel 2 hr 1-0 hr 1.8 hr' 10hr
The timing was s6lected to be typical of a core-melt scenario, except for the onset of the
release of gap activity (duration of coolant activity), which was chosen to be based on the
earliest calculated time of fuel rod failure under design-basis accident conditions (i.e.,
large-break LOCA).
In order to provide a realistic estimate of the shortest time for fuel failure, calculations
were performed using' the FRAPCON2 [23], SCDAP/RELAP5 MOD3.0 [24], and
FRAPT6 [25] computer codes for two PWR Plants (a B&W Plant with a 15x15 fuel rod
array and a W Plant with a 17x17 fuel rod array [16]. The minimum time from the time
of accident initiation until first fuel rod failure was calculated to'be 13 and 24.6 seconds
for the B&W and W plants, respectively. As noted in Reference 4, these estimate are
valid for a double-ended rupture of the largest pipe. For a 6-inch break, the time until
first fuel rod" failure was estimated to6be greater than 6.5 and 10 minutes for the B&W
and -W plahts, respectively. It was expected'that the CE plants ,would have coolant
activity durations similar to the W plants. The review of the Final Safety Analysis
Reports (FSARs) for BWRs indicated that fuel failure may occur significantly later, in
.• I 11 ERI/NRC 02-202Energy ResearchL, %,
the order of several minutes or more. At the time of the publication of NUREG-1465, no calculations for BWRs and CE plants had been performed, using the aforementioned suite of codes. Since that time, BWR calculations have been performed with SCDAP/RELAP5 and are documented in INEEL report "Evaluation of Fuel Pin Failure Timing in Boiling Water Reactors," D. Knudson and R. Schultz, August 1999.
NUREG/CR-5747 [15] provided estimates for the onset of significant fission product release into the containment based on the review of STCP calculated results for 6 reference plants. Significant fission product releases were estimated to commence no earlier than about 30 minutes and 60 minutes for PWRs and BWRs, respectively, after the onset of the accident. More recent calculations [26] for the Peach Bottom Plant, using the MELCOR code, indicated that the duration of gap release for three BWR accident sequences were about 30 minutes as well. On this basis, the duration of gap release phase (onset of early in-vessel release phase) was selected to be 0.5 hours, for both PWRs and BWRs.
The early in-vessel release phase ends when the bottom of the reactor pressure vessel fails, allowing molten core to fall onto the concrete below the reactor pressure vessel. NUREG/CR-5747 provided estimates for the early in-vessel release durations based on the review of STCP calculated results for seven reference plants. The early in-vessel release duration was found to be somewhat longer for BWR plants than for PWR plants. This is due to the lower power-to-moderator ratio and the lower core power density in BWRs, which would delay the time for core degradation and vessel failure. Representative early in-vessel release durations were selected to be 1.3 hours and 1.5 hours, for PWR and BWR plants respectively.
NUREG/CR-5747 [15] also provided estimates for the ex-vessel release durations based on the review of STCP calculated results. Although releases from core-concrete interactions are predicted to take place over a number of hours after vessel breach, the bulk of the fission product releases (about 90%), with the exception of tellurium and ruthenium, are expected to be released over a 2-hour period for PWRs and 3-hour period for BWRs. For tellurium and ruthenium, ex-vessel releases extend over 5 and 6 hours, respectively for PWRs and BWRs. Based on analysis in Reference [15], the ex-vessel release duration for the revised accident source terms was taken to be 2 and 3 hours, respectively, for PWRs and BWRs.
The duration for the late in-vessel release phase was taken to be 10 hours as recommended in Reference [ 15].
2.6 Iodine Chemical Form
The chemical form of iodine and its subsequent behavior after entering containment from the reactor coolant system was investigated in NUREG/CR-5732 [17]. On the basis of this work, NUREG-1465 concluded that iodine entering containment from the reactor coolant system is composed of at least 95% cesium iodide (CsI), with no more than 5% I plus HI. Once within containment, highly soluble CsI will readily dissolve in water pools
Energy Research, Inc. 12 ERI/NRC 02-202
and plate out on wet surfaces in ionic form. Radiation-induced conversion of the ionic
form to elemental iodine could be an important mechanism for revolatilization. If the pH
is controlled to a level of 7 or greater, very little (less than 1%) of the dissolved iodine
will be converted to elemental iodine. If the pH is not controlled, however, a relatively
large fraction of iodine dissolved in containment pools in ionic form could be converted
to elemental iodine in the long-term.
Organic components of iodine, such as methyl iodide, can also be produced over time
largely as a result of elemental iodine reactions with organic materials. A conversion of 4
percent of elemental iodine to organic has been implicitly assumed by the NRC staff in
Regulatory Guides 1.3 and 1.4, based upon an upper bound evaluation of the results in
WASH-1233. However, NUREG-1465 considered a value of 3 percent to be more
realistic. NUREG-1465 concluded that where pH is controlled at values of 7 or greater
within the containment, elemental iodine can be taken as comprising no more than 5
percent of the total iodine released, and iodine in organic form may be taken as
comprising no greater than 0.15 percent (3 percent of 5 percent) of the total iodine
released. Clearly, where pH is not controlled to values of 7 or greater, significantly
larger fractions of elemental iodine, as well as organic iodine could be expected within
containment.
With the exception of iodine (elemental, HI, or organic form), discussed above, fission
products are assumed to be in aerosol form.
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3. PANEL RECOMMENDATIONS AND BASIS FOR RECOMMENDATIONS
FOR HIGH BURNUP AND MOX FUELS
As discussed above, the initial "source term" postulated for the purposes of calculating
off-site doses in accordance with 10 CFR Part 100 [2] was published in 1962 in TID
14844 [5]. Over'the next 30 years, substantial knowledge about severe light-water
reactor (LWR) accidents and the resulting behavior of the released fission products was
developed. NUREG-1465 provided a postulated fission product source term released into
containment that was based upon the understanding of LWR accidents and fission
product behavior developed between 1962 and 1995.
Several elements of NUREG-1465 are noted here for comparison with the current
endeavor to develop source terms for high bumup low enriched uranium and mixed oxide
fuels.
First, NUREG-1465 indicates that release fractions are intended to be representative or
typical, rather than conservative orbounding values, of those associated with a low
pressure core-melt accident. The source term applicability panel employed the same
approach in specifying the release fractions for high bumup LEU and MOX fuels,
although each panel member provided his own release estimates, and in some cases these
individual estimates may be considered as conservative rather than typical.
Second, NUREG-1465 recognized that the source term in the report, particularly gap
activity, might not be applicable for fuel irradiated to high bumup levels, stated to be
burnup levels in excess of 40 GWdIt.- Clearly, the same is true for MOX fuel, given its
different composition.
Third, th6 source terms appearing in NUREG-1465 were developed based on extensive
examinations of both relevant data and calculations that had been developed prior to 1995
combined with expert elicitation. The current development of the source terms for high
burnup LEU and MOX fuels, is best described as an expert elicitation, albeit an expert
elicitation informed by recent test data and insights available for high burnup LEU and
MOX fuels [6-12, 27-32].
3.1 Panel Organization and Elicitation Process
The following process was used to torganize the panel and subsequently elicit panel
member input for the gap release, early in-vessel, ex-vessel, and late in-vessel releases
into the containment for (1) high burnup PWR fuel, (2) high burnup BWR fuel, and (3)
MOX fuel.
1. Panel members were selected'based upon their expertise. Three experts
participated in the development of the NUREG-1150 source terms (J. Gieseke,
T. Kress, and D. Powers), which were 'used as the basis for the development of
-the revised source terms in NUREG-1465. These panel members were enlisted
to partially reconstitute the expert's group providing input to NUREG-1150
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(and NUREG-1465). The remaining panel members (B. Clement and D. Leaver) brought similar expertise to the source term applicability effort. Brief biographies of each of the panel members are presented in Appendix A.
2. Recent additions to the databases for high bumup LEU and MOX fuels were presented and reviewed [6-9, 12] before beginning the elicitation process for each fuel3.
3. The specific characteristics of the fuel and accident sequence type were established and documented (e.g., fuel composition, burnup, cladding type, low-pressure loss-of-coolant accident [LOCA]).
4. The starting point for panel deliberations for high burnup PWR and BWR fuels and MOX fuel was NUREG-1465, which contains tabulations of both PWR and BWR releases into the containment. Releases for eight radionuclide groups (Noble Gases, Halogens, Alkali Metals, Tellurium, Barium/Strontium, Nobel Metals, Cerium, and Lanthanides groups) for each of four accident phases (gap release, early in-vessel, ex-vessel, and late in-vessel) are tabulated.
5. The input of each panel member was elicited and recorded for each fuel, for each accident phase and for each radionuclide group.
6. For the PWR source term, each release fraction and the rationale were elicited from each panel member. If all panel members agreed on the release fraction for a given radionuclide group, a single value was entered into the table. If one or more panel members offered different values for the release fraction for a given radionuclide group, the value offered by each expert was entered in the table. A summary rationale was prepared for each entry in the table.
The historical approach to addressing the many radionuclide species has been to group species with similar chemical properties and behaviors together. NUREG-1465 employs eight such groups. For the present effort, if one or more panel members felt that a subdivision of one of the NUREG-1465 radionuclide groups was needed to reflect the different release fractions represented in the database, the group was divided into subgroups and the release fractions elicited for the subgroups (see, for example, the Cerium
3 It is noted that the panel did not have the benefit of the results of accident sequence analyses using accident analysis models validated by comparison to pertinent test results involving high burnup or MOX fuels. In addition, in many areas, the panel identified gaps in experimental data to support specific panel recommendations. Therefore, the members of the panel have attempted to qualitatively integrate the results of recent tests to predict fission product releases during accidents at nuclear power plants. They have extrapolated phenomenology of core degradation based on existing studies for conventional burnup of LEU fuels to anticipate fission product releases from fuel at bumup levels in excess of about 60 GWd/t. The panel members have also extrapolated the behavior of LEU fuels with conventional Zircaloy cladding to estimate the behavior of mixed oxide fuel with M5 cladding.
Energy Research, Inc. 16 ERI/NRC 02-202
group in Table 3.1). Subgroups were developed for the original NUREG-1465
"groups of Noble Metals, Cerium, and the Lanthanides.
The approach to specifying a-source term in France' differs from that in the
United States. In France, the release fra6tions are specified for two phases: a
gap release phase and a subsequent core degradation phase. The core
degradation phase is not further divided into early in-vessel, ex-vessel," and
late in-vessel phases. For this expert elicitation effort, the French expert (B.
Clement) also did not subdivide the core degradation phase into early in
vessel, ex-vessel and late in-vessel phases. Therefore, in the release fraction
tables in this report, the French expert's values for the core degradation phase
are given in the early in-vessel column and are marked as TR, which stands
for total release from early in-vessel, ex-vessel, and late in-vessel phases.
The French expert did provide publicly released data from the French testing
and analytical programs to the panel. However, for those instances where
French data have not been publicly released but the data indicated some
differences from generally held views, a "flag" was 'declared and this
information appears in the rationale tables. The same approach was used when
French analytical efforts were underway but had not y'et reached the point that
the information could be publicly released.
A. Hidaka presented test data collected by the Japan Atomic Energy Research
Institute (JAERI) at the first panel meeting. However, a JAERI representative
was unable to attend the final two panel meetings. As these were the meetings
at which the PWR, BWR anid MOX source term values were elicited, only
five panrel members particip'ated in the elicitation.
The PWR releases into containment for high bumup' fuel and summary
rationales are presented in Section 3.2 (Table 3.1 and Tables 3.2 through 3.10,
respectively).
7. For the BWR source -term, the value provided by each panel member was
recorded but a rationale for each value offered by each panel member was not
elicited because of time constraints. General statements about the similarities
and dissimilarities of PWR and BWR were discussed and a ýstumzmny of the
general statements for the BWR source term is presented in Section 3.3. The
SBWR releases into containment for high burnup fuel are presented in Table
3.11.
8. For the MOX source term, both the value and the 'rationale offered-by each
panel member were recorded.' The -MOX releases into -containment and
summary rationales are presented in Section 3.4 (Table 3.12 and Tables 3.13
through 3.21, respectively).
ERI/NRC 02-202Energy Research, Inc. 17
9. During the first panel meetings, the experts indicated that the physical and
chemical forms of the revised source terms as defined in NUTREG-1465 are
also applicable to high burnup and MOX fuels. Therefore, during subsequent
meetings, the panel members did not discuss this issue.
3.2 PWR Accident Source Term
3.2.1 PWR Accident Sequence
The PWR accident sequence selected for NUREG-1465 [1] was a low-pressure core-melt
accident. The panel followed the precedent established for NLTREG-1465 and selected a
low-pressure core-melt accident as the scenario for which the source term for high burnup
PWR fuel was to be evaluated. However, the scenario was not rigorously "low pressure"
in terms of timing and reactor cooling system deposition. The intent was to conduct a
rebaselining effort high burnup and MOX fuels.
3.2.2 PWR Fuel Characteristics
The following fuel characteristics were specified for the high burnup PWR fuel.
* A maximum burnup of 75 GWd/t * A core average bumup of approximately 50 GWd/t
* Zirlo 4 or M55 cladding
As a prelude to the elicitation step, panel members considered the effect of high burnup
on PWR fuel through discussions of governing phenomenological processes and issues
that can potentially impact core degradation and fission product release behavior of high
burnup fuels as compared to LEU fuels [I 1-12, 27].
3.2.3 PWR Accident Source Term
The PWR releases into containment, as specified by the source term applicability panel,
are summarized in Table 3.1.
The NUREG-1465 values for PWR releases into containment are shown in parentheses
for each phase for the duration and each radionuclide group. For those cases for which
the panel agreed upon a single value, only one value is entered e.g., the duration of the
gap release phase or the halogen release fractions during all four phases. However, when
the panel members did not agree on a single value for a given release, one value was
entered for each panel member. As explained previously, the approach to specifying the
source term in France differs from that in the United States. A value is specified for the
gap release. A second value is specified for the fuel release. However, this latter value is
4 Note that the data base on high burnup fuel available from foreign sources will not include data for fuel
clad m Zirlo 5 M5 is an advanced cladding material and it could be used in combination with any LWR fuel (e.g, high
burnup, MOX, etc).
ERI/NRC 02-202Energy Research, Inc. 18
the total release, designated as TR in the table, and there are no further entries for the
later phases of the accident.
Both the. release fraction for each radionuclide group and an accompanying rationale
were -elicited from each panel member. A surmmary rationale was prepared for each
release fraction and the panel reviewed this summary. The resulting rationales for each
ac'ident phase and for the duration and each radionuclide group are presented in Tables
3.2 through 3.10.
The panel also considered additional research needs during the course of its deliberations.
These are also summarized in Tables 3.2 through 3.10. In addition, the panel members
were also asked to consider research needs separately from the panel meeting and to
document these in a letter. The individual -panel member letters identifying research
needs are provided in Appendix B.
3.3 BWR Accident Source Term
3.3.1 BWR Accident Sequence
The BWR accident sequence selected for NUREG-1465 [1] was a-low-pressure core-melt
accident.
The panel followed the precedent established for NUREG-1465 and selected a low
pressure core-melt accident, as the scenario for which the sourceterm for high bumup
fuel Was evaluated.
3.3.2 BWR Fuel Characteristics
The following fuel characteristics were specified for the high burnup BWR fuel.
* A maximum bumup of 75 GWd/t.
* A core average burnup of approximately 50 GWd/t.
* The cladding material is Zircaloy-2, most predominately in the annealed, frlly
recrystallized condition with a zirconium-based inner liner, although cold-worked
stress relieved material and non-liner applications also exist. 'The zirconium liner
can contain varying amounts of alloy additions, intended for post-defect corrosion
resistance.
The'BWR fu-el designs are increasingly evolving and they are characteristically becoming
more similar to those of PWRs. This growing similarity of the fuel designs affected the
panel's deliberations.
-ERI/NRC 02-202Energy Research, Inc. 19
Tabl 3.1 PWR Releases Into Containment (High Fiimuin Fuiela
Gap Release Early In-Vessel Ex-Vessel Late In-Vessel
Duration (Hours) 0 4 (0 5)' 1.4 (13) 20 (20) 10.0 (100)
Noble Gases 0.05; 0.07; 0 07; 0 07; NE 3 0.63, 0.63; 0 63; 0 65; 1.OTR 0 3 (0) 0 (0) (0.05) (0.95)
Halogens 0.05 (0.05) 0.35; 0.95TR (0 35) 0.25 (0.25) 0.2 (0.1)
Alkali Metals 0.05 (0.05) 0.25; 0.90TR (0 25) 0.35 (0.35) 0.1 (0 1)
Tellurium group 0.005 (0) 0.10; 0.30; 0.30; 0.35, 0.7TR 0.40 (0.25) 0.20 (0.005) (0.05)
Barium, Strontium 0 (0) 002; woic4 (0.02) 0.1 (0.1) 0 (0)
Noble Metals (0) (0.0025) (0.0025) (0)
Mo, Tc 0 0 15, 0 2; 0.2; 0.2; 0.7TR 2 0 02; 0.02; 0.2; 0.2; TR 0; 0; 0.05; 0.05, TR
Ru, Rh, Pd 0 0 0025; 0.0025; 0.01, 0.01; 0 0025; 0.02; 0.02; 0.02; TR 0 01; 0.01; 0.01; 0 10, TR 0.02TR
Cerium group (0) (0.0005) (0.005) (0) Ce 0 0.0002, 0 0005; 0.01; 0.01; 0.005; 0 005, 0 01; 0.01; TR 0
0.02TR Pu, Zr 0 0.0001; 0 0005; 0.001; 0.002; 0 005, 0 005; 0.01; 0.01; TR 0
0 002TR Np 0 0 001; 0.01; 0.01; 0.01; 0 005; 0 005; 0.01; 0.01; TR 0
0.02TR
Lanthanides (one group5) 0; 0; 0; (0) 0.0005; 0.002; 0.01 (0.0002) 0 005; 0.01; 0.01 (0.005) 0; 0; 0 (0) La, Eu, Pr, Nb 0; 0 0 0002; 0.02TR 0 005; TR 0; TR
Y, Nd, Am, Cm 0; 0 0.0002; 0.002TR 0.005; TR 0; TR
Nb 0; 0 0.002; 0.002TR 0.005; TR 0; TR
Pmo, Sm 0; 0 0.0002; 0.002TR 0.005; TR 0, TR
a Note that it was the panel's understanding that only about 1/3 of the core will be high bumup fuel. This is a significant deviation from the past when accident analyses were performed for cores that were uniformly burned usually to 39 GWd/t
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Table 3.1
20 ERI/NRC 02-202
_ ... . , --
Energy Research, Inc.
F-7 F- F F -' i [- - I-.. ., F' -- - .. . ,r- - - F ---- .. . . .. . - -,7. . -- I . . .. [ I. . .
Footnotes to Table 3 1
1 The numbers in parenthesis are those from NUREG-1465, Accident Source Terms for PWR Light-Water Nuclear Power Plants (Table 3.13).
2 TR = total release. The practice in France is to assign all releases following the gap release phase to the early in-vessel phase. 3 NE= No entry; the panel member concluded that there was insufficient information upon which to base an informed opinion. 4 Barium should not be treated the same as Strontium. There is experimental evidence that barium is much more volatile than strontium. VERCORS and
HI/VI (ORNL) experiments cited; these show a 50% release from the fuel and a 10% delivery to the containment. Strontium has a 10% release from fuel and 2% to the containment, based upon all data available to date.
s Three panel members retained the NUREG-1465 lanthanide grouping, e.g., one group, while two panel members subdivided the group into four subgroups.
F__
A I ,} ,tj
21 ERI/NRC 02-202
Table 3.2 Rationales for Duration Entries in Table 3.1 Gap Release The NUREG-1465 duration for this interval is 0.5 hr. The panel concluded that for high bumup fuel, the duration of the
interval is 0.4 hr. The end point of the gap release phase is defined as the release of significant fission products and this process is accelerated with high burnup fuel. The shortened time reflects the qualitative understanding that the fuel has
restructured, putting more gas near the periphery and accelerating the release kinetics of volatile fission products. Data
from French VERCORS experimental program shows that early in-vessel release starts earlier with high burnup fuel.
Needs: Perform calculations with a code validated with applicable data such as is being generated in the VERCORS experiment.
Early In-Vessel The NUREG-1465 duration for this interval is 1.3 hr. This phase ends when the bottom head of the reactor pressure
vessel fails. The panel concluded that the total time for accident initiation to the end of the early in-vessel phase should
be the same as the value in NUREG-1465, i.e., 1.8 hr., thereby fixing the duration of this interval at 1.4 hr. Panel
members thought degradation processes might change with high bumup fuel, but that such outcomes can only be
understood with integrated experiments.
Needs: Need integrated bundle experiments with high burnup fuel, e.g., PHEBUS. Need to translate the data into models,
such that whole-core calculations can be made. Need to investigate experimentally the degradation of cores with high
bumup fuel to see if a qualitatively different core degradation model is needed.
Ex-Vessel The NUREG-1465 duration for this interval is 2 hr. The panel concluded that the same value was applicable for high burnup fuel. The dominant ex-vessel process is zirconium oxidation. A significant change in this process is not expected for high burnup fuel.
Late In-Vessel The NUREG-1465 duration for the late in-vessel phase is 10 hr. The panel concluded that the same value was applicable for high burnup fuel. Several processes dominate during this phase. They are (1) revaporization of deposited radionuclides, (2) degradation of residual fuel in core region, (3) air ingress. Existing analyses only address the first two Data to assess the contribution of the third process is lacking. Releases due to degradation of residual fuel to the ex-vessel category are considered in the ex-vessel category to narrow the time frame from 10 hours to 2 hours. Until additional data are available, the panel has no justification for changing the duration of this phase.
Needs: Experimental investigation of air ingress to investigate the competition between degradation and fission product
release is essential.
Energy Research, Inc. ERI/NRC 02-20222
I - F- -- 7 7_ F -- F- --- -- F 7 -FI
Tnlkli- I'A Rionnles for Noble Gases Entries in Table 3.1Gap Release
Early In-Vessel The NUREG-1465 early in-vessel release was 0.95. ýThe panel concluded that a reduced release traction is applicaobe out that this conclusion was independent of fuel burnup, i.e., the panel concluded that the release fraction reported in
NUREG-1465 is too high. The panel noted that only a portion of the core is involved in the accident through this phase.
Therefore, noble gases can only be released from that portion of the core involved in the accident. For the LB LOCA, the
panel believes 60-70% of the core is involved in the accident by this stage. A release fraction of 63% was selected.
The NUREG-1465 gap release was 0.05. A majority of the panel concluded that an increased release fraction is
applicable for high burnup fuel. A value of 0.07 was selected. Data from the Japan Atomic Energy Research Institute
(JAER") was cited [9, 2816. The JAERI test featured high reactivity insertion rates characteristic of a rod ejection
accident,(note that RAIs are not core melt precursors and are not characteristic of the low pressure accidents, generally
considered by the panel). The data show an acceleration of gap release with bumup, with a discernable threshold near 42
GWd/t. The highest fuel burnup level discussed for the JAERI test was 50 GWd/t. French data for high burnup fuel
indicate a value of about 5% at 60 GWd/t (FLASH 5 Test). A release fraction as high as 0.10 was considered by the
panel, but the lower value of 0.07 was adopted to account for the slower rate of energy deposition during a large LOCA
and in recognition of the French data. However, the specified burnup for panel consideration is 75 GWd/t, causing,
possibly, a higher release than the 5% measured in the French test. One panel member weighted the French results higher
than the JAERI results on the basis of proto-typicality of the experimental conditions to a low-pressure LOCA and
concluded that a lower release rate of 0.05 was more applicable.
Needs: The JAERI data was cited by the panel was an important factor in selecting an increased release fraction.
However, the panel recognized that the high-energy deposition rate could be an important factor in the increased release
fraction. Therefore, the panel concluded that further experiments with high burnup fuel under conditions more
representative of a large LOCA are desirable to determine if higher gap releases are realized with high burnup fuel in slower events.
-A.
6 The results of other recent Japanese experimental data are reported in References [28] through [30].
ERI/NRC 02-202Energy Research, Inc.
LI
I ' -[--- F--- [--F .... (---I --
_,J1
23
Rationales for Noble Gases Entries in Table 3.1 (continued)
Energy Research, Inc.
Ex-Vessel The NUREG-1465 ex-vessel release was 0.0. i.e , all noble gases were released by the end of the early in-vessel phase. The panel concluded that the release fraction for high bumup fuel for this phase should be 0.3, which constitutes the remainder of the release for noble gases. The relocated core debris does not contain any noble gases. The panel noted that the gap release and early in-vessel phases are discrete phases in time. However, the ex-vessel and late in-vessel phases overlap in time. The panel recognized that releases would occur in-vessel during the late in-vessel phase However, the panel elected to bias releases occurring from residual fuel early in the late in-vessel phase by attributing the release to the ex-vessel phase. The panel chose this course because assigning the release to the late in-vessel phase would allocate the release to the 10-hour period associated with the late in-vessel phase. Because the releases are expected to occur early in the late in-vessel phase, the panel concluded that issue of timing, with respect to release fractions, is best handled by associating the release with the ex-vessel phase. NUREG/CR-5747, which was referenced in NUREG-1465 as the basis for the release fraction, would have the total release through the early in-vessel phase of about 80%. The NUREG/CR5747 values were based upon CORSOR calculations, supplemented by expert elicitation. The CORSOR calculations are known to be conservative for noble gases and thus the panel concluded that a lower release of 0.70 for the early in-vessel phase should be used.
Late In-Vessel The NUREG-1465 late in-vessel release was 0.0. The panel understands that some release of noble gases in this phase is possible but concluded that the release would be early in the phase. Given the length of the late in-vessel phase (10 hours), the panel elected to assign all releases following the early in-vessel phase to the ex-vessel phase.
Table 3.3
24 ERI/NRC 02-202
r� t i- r
Table 3.4 Ration• Gap Release
Early In-Vessel
Ex-Vessel
Late In-Vessel
-I
fI•trw T--Tlnopn Pntrie• in Table 3.1
The NUREG-1465 gap release was 0.05. The halogen releases from the gap are dominated by the vaporization of
halogens into the gas flow from the ruptured fuel rod. The release is determined then by temperature and the total volume
of gas released immediately following fuel clad rupture and neither the temperature nor the volume of gas in the rod will
be greatly affected by burnup. The panel concluded that the same value was applicable for high burnup fuel. French
reactor data for high bumup fuel indicates that the amount of gas in the gap reaches a value of about 5% at about 60
GWd/t. An in-pile experiment for fuel with a burnup of 50 GWd/t and under LOCA conditions indicates a release of 5%.
The NUREG-1465 early in-vessel release was 0.35. The panel concluded that the same value was applicaoble or , ig
burnup fuel. Several panel members noted that the releases reported in NUREG-1465 were too large, because the
NUREG-1465 releases were predicated based on CORSOR calculations, which is believed to overestimate Halogen
releases. Nevertheless, since a significant burnup dependence was identified, the same release fraction was retained.
1Jlppa. Py-nriments needed to understand how high burnup fuel degrades.
The NUREG-1465 ex-vessel release was 0.25. The panel concluded that the same value was applicable for high burnup
fuel. The panel noted that the gap release and early in-vessel phases are discrete phases in time. However, the ex-vessel
and late in-vessel phases overlap in time. The panel recognized that releases would occur in-vessel during the late in
vessel phase. However, the panel elected to bias releases occurring from residual fuel early in the late in-vessel phase by
attributing the release to the ex-vessel phase. The panel chose this course because assigning the release to the late in
vessel phase would allocate the release to the 10-hour period associated with the late in-vessel phase. Because the
releases are expected to occur early in the late in-vessel phase, the panel concluded that'issue'of timing, with i'espect to ,
r~lease fractiins,'is best handled'by associating the ielease'with'the ex-vessel phase.
The NUREG-1465 late in-vessel release was 0.1. The panel concluded that the release for this phase snoula oe u.2., 1ne *1~ f-, ;^ r f4 nui s and rievanori7zitiofl off the bniniu
increased release was variously attnl~uieu to self-neatLng~ FUDl~~~ %,ov ,, ........ F ........ -- , system associated with air ingress and the circulation of air through the piping.
Needs: The post-test analyses of PHEBUS data should be reviewed for information and insights regarding revaporizatio:n.
ERI/NRC 02-202Energy Research, Inc. 25
-1
F• ... F - i F -... = - I .... . . I ------ F ... ý 1 -... 1--, - - I
Table 3.5 Rationales for Alkali Metals Entries in Table 3.1 Gap Release The NUREG-1465 gap release was 0.05. The panel concluded that the same value was applicable for high burnup fuel.
The gap release is via vaporization into the void volume and neither the chemistry of the Cs and Rb nor temperatures changed significantly for high bumup.
Early In-Vessel The NUREG-1465 early in-vessel release was 0.25. The panel concluded that the same value was applicable for high burnup fuel. Two factors for retaining the value were indicated. Various cesium compounds are released, some of which have reduced vapor pressures and are, therefore, less volatile. However, hot spots are thought to increase the release. These two processes are thought to offset and the release fraction remains the same. One panel member was supportive of a release fraction of 0.3 based upon separate effects release rates just slightly below the release rates for iodine.
Ex-Vessel The NUREG-1465 early ex-vessel release was 0.35. The panel concluded that the same value was applicable for high burnup fuel. The panel noted that the gap release and early in-vessel phases are discrete phases in time. However, the exvessel and late in-vessel phases overlap in time. The panel recognized that releases would occur in-vessel dunng the late in-vessel phase. However, the panel elected to bias releases occurring from residual fuel early in the late in-vessel phase by attributing the release to the ex-vessel phase. The panel chose this course because assigning the release to the late invessel phase would allocate the release to the 10-hour period associated with the late in-vessel phase. Because the releases are expected to occur early in the late in-vessel phase, the panel concluded that issue of timing, with respect to release fractions, is best handled by associating the release with the ex-vessel phase.
Late In-Vessel The NUJREG-1465 late in-vessel release was 0.1. The panel concluded that the same value was applicable for high burnup fuel.
Needs: Experiments are needed to better characterize the revaporization of cesium.
Energy Reseaich, Inc. 26 ERI/NRC 02-202
i I I II I I
F---- 7� V.--. V -- V F� K'
Table 3.6 Rationales for Tellurium Group Entries in Table 3.11 Gap Release The NUREG-1465 gap release is 0. The panel concluded that a small but increased release fraction of 0.005 is applicable
for high bumup fuel. A non-zero value was felt appropriate because gap releases increase with time. The panel felt that
the uncertainty was high and that additional test data was needed (see Needs).
Needs: Experiments with high burnup fuel under LOCA conditions to measure gap releases are needed. The applicability
of the proposed PHEBUS LOCA experiments should be reviewed. Early In-Vessel The NUREG-1465 early in-vessel release is 0.05. The panel concluded that an increased release fraction is applicable for
high bumup fuel. A value of 0.30' was specified by a majority of the panel. The panel noted that PHEBUS FPT-1 test
results indicate high in-vessel releases of tellurium, which decays to iodine. As the PHEBUS tests were designed and
directed to fission product measurement, there is justification for basing source term applicability on PHEBUS results.
Note, in PHEBUS tests the release of Te occurred after the escalation in temperature due to metal water reaction, and the
fact that tellurium is inherently volatile. Questions were also raised by one of the panel members about the non
prototypical nature of the PHEBUS tests due to the very high metal oxidation that was experienced in the high steam
injection period. Other tests show lower Te releases, apparently due to binding of the Te with other materials. The Te
release is very much dependent upon the manner in which the accident scenario evolves. This can lead to a large
variation in Te release. Another issue discussed was the degree to which the Te subsequently interacts with other
materials, which would reduce the release to containment. The range of values offered by the panel is between 10% and
35%. The panel noted that even if select the lowest value of 10% is used, this value represents a significant change in
regarding the tellurium source term. One panel member stated that in the PHEBUS test, the tellurium release lagged the cesium release. The other factors
cited were that the measured values from TMI-2 (TMI-2 core average burnup was 8 GWd/t) shows low tellurium releases
and the event duration of 1.4 hours for the PWR source term applicability selected by the panel is shorter than the
duration of the FPT-1 test. This panel member stated that a lower release rate of 0.1 to 0.15 was more applicable.
Needs: The differences between the PHEBUS, VERCORS and ORNL tests should be reconciled. The perception thA'
Tellurium doesn't come out until 95% of the cladding is oxidized comes from the ORNL and the SFD tests. Experiments
with high burnup fuel under both severe accident and LOCA conditions are recommended.
Ex-Vessel The NUREG-1465 ex-vessel release is 0.25. The panel concluded that an increased release fraction is applicable for high
bumup fuel. A value of 0.40 was specified. The panel concluded that approximately 60%' of the tellurium is released
from the fuel and 40% remains in fuel, which will be released from residual fuel after the vessel head fails or from the
core-concrete interaction. The panel also recognized that chemical interactions with vapors from the control rods and
other materials,- tellurium transport is via tellurides, not as elemental tellurium. Consequently tellurium doesn't chemically react with the piping system. Note: The tellurium releases occur in-vessel but after the time that the bottom head fails and so is counted as an ex-vessel release. The release is actually occurring in the vessel and during the transit through the vessel.
ERI/NRC 02-202Energy Research, Inc.
F ..... V ... -....
27
Tabl 3.6 Rationales for Tellurium Giroun Entries in Table 3_1 (eontinied'•Late In-Vessel The NUREG-1465 late in-vessel release is 0.005. The panel concluded that an increased release fraction is applicable for
high burnup fuel. A value of 0.20 was specified. In contrast to the NUREG-1465 assessment in which the total release fraction through the late in-vessel phase was 0.305, the panel concluded that all tellurium will be released by the end of this phase. Several important processes were identified. First, the amount of tellurium present is significant and it is not bonded to surfaces. Rather, it is bonded to aerosols and more easily released. Second, once the piping system is opened and oxygen partial pressure increases, all the tellurides are oxidized to TeO and telluric acid, both of which are highly volatile.
The changes in the Tellurium releases from NUREG-1465 reflect new insights from test programs and are not associated with high bumup fuel specifically.
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Table 3.6
28 ER1/NRC 02-202
P�tnnnIi�c� fnrfl�iriiim �nd 5Urontiiim Pntiies in Table 3.1
Results were presented to the panel by T. Kress. Although barium and strontium behave differently, the panel elected to treat them as a class and a representative value of-the release fraction
used. For background, the panel was informed that.in the draft NUREG-1465, bariumand strontium were treated separately. They were
combined for the final document because they were judged at that time to have similar behavior.
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TalII• " "7
Gap Release The NUREG-1465 gap release is 0.0. The panel concluded that the same value was applicable for high bumup fuel.
Early In-Vessel The NUREG-1465 early in-vessel release is 0.02. The panel concluded that the same value should be retained for high bumup fuel. Modeling results were considered 1. Barium and strontium are modeled separately and a release of 0.03 is
predicted. Given the modeling uncertainties, there was insufficient justification to alter the NUREG-1465 value. There is experimental evidence that barium is much more volatile than strontium; the VERCORS and HI/VI (ORNL) experiments cited. The panel discussed whether the two should be considered separately but retained the NUREG-1465 grouping. 2
Needs: experimental investigations to resolve competing effect and the absolute value of the release fraction are needed
for high burnup fuel. The increase of the diffusion coefficient for these species and the oxygen potential that depresses the volatility of both species were identified as the competing effects.
Ex-Vessel The NUREG-1465 early ex-vessel release is 0.1. The panel concluded that the same value should be retained for high bumup fuel. Thermodynamic calculations performed by the French support a combined release of 0.1 with .01 being barium and 0.09 strontium. The release of barium and strontium ex-vessel is proportional to the amount of zirconium metal that comes ex-vessel. However, the degree to which high burnup affects the amount of ex-vessel metal is unknown. Lacking this information, which again supported the retention of the NUREG-1465 value.
_Needs: An improved understanding of high burnup fuel degradation is needed; experimental data is required.
Late In-Vessel The NUTREG-1465 late in-vessel release is 0. The panel concluded that the same value should be retained forhigh burnup fuel. Uncertainties in the resuspension assessment were noted. Large deposits of barium and strontium have been found above the fuel and the potential for release of this material exists (See Needs). It was also stated by one'of the panel' members that it is'more likely, that large buildup of deposited Ba and Sr will provide additional heat sources to drive the revaporization of more volatile fission products that have been released and previously deposited.
Need: A better understanding of resuspension and revolatized processes is needed; experimental data are required.1
2
V� F� V r F F� F 7 7" f - F� V� F rF . ... F .. . . I -. .. ..... r - [f . ...
ERI/NRC 02-20229
Table 3.8 Rationales for Noble Metals Entries in Table 3.1The NUREG-1465 gap release is 0. The panel noted that the release is non-zero but sufficiently small that the NUREG1465 value was retained.
The NUREG-1465 early in-vessel release is 0.0025. The range of experimental results is high and uncertainties are large. The ability to differentiate via prediction does not exist. The four species in this group exhibit differences in behavior. Two of the species are very volatile (Mo, Tc). Based on VERCORS data, Mo and Tc release 90% of the noble metals from fuel and 70% to containment. The Ru release is 10% from the fuel and 2% to the containment. The Rh release is 30% from the fuel and 6% to the containment. The panel created two subgroups, the first contains Mo and Tc and the second contains Ru and Rh. Several factors led to the creation of two groups. Within the original single grouping, there were differences in volatility and biological effects. Temperature increases were cited as an important factor affecting release rates. It was noted that even if temperatures remain nearly constant and fuel motion occurs, the release rates are affected. Similarly, gas release rates at constant temperature can affect release fractions. The original groupings were influenced by code capabilities and modeling approaches. The choice by the panel to divide the Noble Metals into two subgroups may impact analytical code requirements.
Needs: Need data that can be used in model (various releases at various times and temperatures; either data with time/temperature plateaus or several tests as a function of burnup). Need to distinguish between Ru and Mo).
Ex-Vessel The NUREG-1465 ex-vessel release of 0.0025 is retained. Ruthenium is under predicted in VANESSA by perhaps three orders of magnitude. However, this information was available to the NUREG-1465 panel and was, therefore, factored into the NUREG-1465 release fraction.
Needs: correct code models to handle increased Ru releases.
Late In-Vessel The NUREG-1465 late in-vessel release is 0.0. The noble metals are released and deposited but whether they are revaporized is unclear (See Needs). The release of ruthenium deposits is quite likely if there is air present.
Needs: An improved understanding of revaporization processes for noble metals is needed; experimental data are required.
Gap Release
Early In-Vessel
Energy Research, Inc. 30 ERI/NRC 02-202
[_... F- - [ F . .- F....
Table 3.9 Rationales for Cerium Group Entries in Table 3.1
Gap Release The NUREG-1465 gap release was 0. The panel concluded that the same value was applicable for high burnup fuel.
Early In-Vessel The NUREG-1465 early in-vessel release is 0.0005. Some of the panel members supported a higher release fraction.
Based on VERCORS and other experiments, e.g., TMI-2 and SFD 1-4 [34], the Np release is 0.10 from the fuel and 0.02
to the containment. The Pu release from the fuel is 0.01 and 0.001 to the containment. A significant release of Ce was
measured in the ORNL VI-5 test and this outcome was also seen in some VERCORS experiments. By analogy with the
release of La as measured in VERCORS, a Ce release from the fuel of 0.1 and 0.02 to the containment is predicted. The
panel created three subgroups. The first consists of Ce, the second contains Pu and Zr and the third consists of Np.
Several factors led to the creation of the three groups. The differing biological impacts of the radionuclides in the three
subgroups was indicated. Also considered were the indications of different release rates obtained in the available
experiments. Finally, there were differences in the inventory of the species that favored creation of three subgroups. The
choice by the panel to divide the Cerium group into three subgroups may impact analytical code requirements.
The panel moved the fission product Zr from the Lanthanides group to the Cerium group. The panel noted that Zr had a
very low volatility, much like Pu. Also, it is a tetravalent species, as are the other species in the Cerium group.
Needs: An improved understanding of how the oxidation potential in high bumup fuel is behaving. Transieht data with
two or more plateaus for use in models. Ex-Vessel The NUREG-1465 ex-vessel release is 0.005. Two components for the release were noted, mechanical release as bubbles
burst at the surface and vapor release dependent upon the amount of zirconium present.
Late In-Vessel The NUREG-1465 late in-vessel release was 0., The panel concluded that the same value was applicable for high burnup
fuel.
Needs: An improved understanding of the volatilities as well as revaporization of the species in the cerium group is
needed; experimental data are required.'
ERI/NRC 02-202Energy Research, Inc.
F- ... . . [ . .. [ " - [ . .
31
Table 3.10 Rationales for Lanthanides Entries in Table 3.1
Energy Research, Inc.
The NUREG-1465 gap release is 0. The panel concluded that the same value was applicable for high bumup fuel.Early In-Vessel The NUREG-1465 early in-vessel release is 0.0002. Three of the panel members concluded that the original single group
was still applicable because they exhibited similar chemical behaviors. Another panel member concluded a different release rate was warranted only for Nb and only for the early in-vessel phase. Otherwise, a single release rate was deemed adequate by this panel member to represent the release rates for the remaining species within the group as well as for the other phases of the accident. Another panel member felt that there was justification for creating two subgroups based upon data from VERCORS, Phebus FPT-1, TMI-2 and SFD 1-4 [34]. The first subgroup consists of La, Eu, Pr and Nb. These species are characterized by a 0 02 total release to the containment for the early in-vessel phase. The second group consists of the remaining species.
Needs: Data on the Lanthanides lacking, data to be obtained for and analyzed with models. Ex-Vessel The NUREG-1465 ex-vessel release is 0.005. The panel concluded that the same value was applicable for high bumup
fuel. Late In-Vessel The NUREG-1465 late in-vessel release is 0. The panel concluded that the same value was applicable for high bumup
fuel.
Needs: Assuming the existence of La deposits, an improved understanding of the resuspension is needed; experimental data are required.
32 ERI/NRC 02-202
Gap Kelease
3.3.3 BWR Accident Source Term
The BWIR releases into containment, as specified by the source term applicability panel,
are sumrnarized in Table 3.11.
The NUREG-1465 values for BWR releases into containment are shown in parentheses
for each phase and for the duration and each radionuclide group. For those cases for
which the panel agreed upon a single value, only one value is entered (e.g.,'the duration
of the gap release phase or the halogen releases during the gap release phase). However,
when the panel members did not agree on a single value for a given release, one value
was entered for each panel member.
As France does not deploy BWRs, the French panel member, while contributing to
general. ýtechnical discussions about -the source term, did not participate in the
specification of numerical values for BWR releases into containment.
The panel operated under time constraints that limited the collection of rationales for
values offered by each panel member for the BW.R releases into containment. In an effort
to accommodate to the time constraints, the panel first discussed PWR and BWR
differences that might affect the source term. The following items were discussed as a
prelude to eliciting values for the BWR releases into containment.
"* BWRs have a higher zirconium inventory than PWRs due to the presence of fuel
channels. 'This factor was accounted for in NUREG-1465.
"* The BWR power density is lower, approximately,60% of a PWR, and the system
contains more water that would tend to slow the progression of accident
sequences. However, ADS actuation may speed up the progression and limit the
effect of the lower power density. " Stteam separators in the BWR upper plenum can serve as deposition sites [32]. A
panel member questioned whether this effect had been considered in NUREG
1465. "• BWRs employ boron carbide control rods rather than the silver-indium-cadmium
control, rods used in PWRs. Several, panel members noted I that the :different
materials would affect tellurium behavior. This effect was thought to have been
considered in NUREG-1465. "* The BWR power profile is thought to be flatter. This could'alter, relative to the
PWR, the fraction of the core affected by an accident and thus the amount of core
experiencing early melting and relocation. It was the belief of some panel
m~mbers that this factor had not been' accounted for in NUREG-1465.
* The presence of the Zircaloy channel boxes in BWRs tend to result in a more
reducing environment during core degradation compared with'PWRs.
Also considered by the panel was the power upgrade effort for BWRs that will lead to a
20% increase in core power for all or nearly all operating BWRs.
ERI/NRC 02-202Energy Research, Inc. 33
Table3.11 BWR Releases Into Contaimnent (Hi%Žh Bumun Fiiefl
Gap Release Early In-Vessel Ex-Vessel Late In-Vessel Duration (Hours) 0 4 (05)' 1.6 (1.5) 3.0 (3 0) 10.0 (10.0)
Noble Gases 0.05; 0.07; 0 07; 0 07 (0.05) 0.65; 0.76; 0.76; 0 93 (0.95) 0; 0.17, 0 17; 0.3 (0) 0 (0)
Halogens 005 (005) 0.25; 0.30, 0.35; 0.40 (0.25) 0.15; 02, 0.3; 035 (0.30) 0.1; 0.1; 0.12, 0.2 (0.1)
Alkali Metals 005 (005) 0.2, 0.25; 0 3; 0.4 (0.20) 0.1, 0 3; 0.35; 0 35 (0.35) 0.1; 0.1; 0 2; 0 22 (0.1)
Tellurium group 0 005 (0) 0.05, 0 06; 0 06; 0.1 (0.05) 025 (0.25) 0.005; 0.01; 0 01; 0.01 (0.005)
Barium, Strontium 0 (0) 0 02 (0.02) 0 1 (0 1) 0; 0, 0, 0 01 (0)
Noble Metals (0) (0 0025) (0 0025) (0)
Mo, Tc 0 0 0025; 0.2; 0.2; 0.2 0.0025; 0.02; 0.2; 0.2 0; 0; 0; 0.05
Ru, Rh, Pd 0 0 0025; 0.0025, 0.0025; 0 01 0.0025; 0.0025, 0 02, 0 02 0; 0.01; 0.01; 0 10
Cerium group (0) (0.0005) (0 005) (0)
Ce 0 0.0002, 0.0005; 0 01; 0 01 0.005, 0.005, 0 01; 0 01 0
Pu, Zr 0 0 0001; 0 0005; 0.001; 0.002 0 005; 0.005; 0.01; 0.01 0
Np 0 0 001;0 01; 0 01; 0.01 0.005, 0 005, 0 01; 0.01 0
Lanthanides (one group2 ) 0, 0, 0(0) 0 0005, 0 002; 0 01 (0.0002) 0.005; 0.01; 0 01 (0 005) 0; 0, 0 (0)
La, Eu, Pr, Nb 0 0.0002 0.005 0
Y, Nd, Am, Cm 0 0.0002 0.005 0
Nb 0 0.002 0.005 0 Pmo, Sm 0 0.0002 0.005 0
2 2
The numbers in parenthesis are those from NUREG-1465, Accident Source Terms for BWR Light-Water Nuclear Power Plants (Table 3.12) Three panel members retained the NUREG-1465 lanthanide grouping, e.g., one group, while one panel member subdivided the group in to four subgroups.
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Table 3.11
34 ERI/NRC 02-202
Individual rationales were not elicited for each accident phase and radionuclide group for
the BWR.
The panel'did not consider additional BWR-specific research needs during the course of
its deliberations. As with the PWR source term, the panel members .were asked to
consider research needs separate from the panel meetings and to document these in a
letter. The iridividual panel member letters identifying research needs are provided in
Appendix B.
3.4 MOX Accident Source Term for Light-Water Nuclear Power Plants
The panel agreed upon an approach to be taken in considering the MOX releases into
containment. -The approach consisted of the following elements.
• The tabulated fission product release fractions are for MOX assemblies only.
* Assume MOX assemblies are distributed uniformly throughout the core.
• Whether MOX or LEU, the assembly undergoes the same thermal transient.
' The MOX assembly passes through a temperature transient that damages the fuel.
LEU assembly also passes through a temperature transient that damages the fuel.
* At the end of the early in-vessel phase,'50% of the core is badly damaged and will
be released immediately upon failure of the vessel lower head. -Some portion of the 50% of the core remaining in the vessel is also damaged and
participates in the early in-vessel release., Three-fifths of the remaining core loses
one-half of its volatile inventory.
* During the ex-vessel phase; 100% -of the core eventually ends up outside the
vessel and on the concrete floor. .
* During the ex-vessel phase, some of the fission products deposited on the RCS
surfaces revaporize.
The panel also addressed and developed a method for applying the values for the MOX
releases into containment to an entire core containing both MOX and LEU fuel
assemblies. The -application process is as follows.
o To apply results of these tables to a core containing both, MOX and LEU
assemblies, define the fraction of the MOX fuel in the core to be 'f'. Define the
fraction of LEU to be "l-f'.
IMox(i) = inventory of the iPh radionuclide in the MOX fuel
ILEu(i) = inventory of the ith radionuclide in the LEU fuel
RFrt6x(i) = release fraction of the ith radionuclide from the MOX fuel
RFL~u(i) =release fraction of the io radionuclide from the LEU fuel
Then, the release fraction from themixed core is:
ERVINRC 02-202Energy Research, Inc. 35
RF(i) = f * RFMOx (i) * IMOX (i) + (1 - f) * RFLEU 0) * ILEU (i) (3.1) f * IMOX (i) + (1- f) * ILEU (i)
"* For high burnup LEU fuel, the values are those in the tables generated by the panel (i.e., Tables 3.1 and 3.11, for PWRs and BWRs, respectively).
"* For LEU fuel that is not at high burnup, use the values from NUREG-1465, even though some of the values could be updated based upon the database now available.
3.4.1 MOX Accident Sequence
The accident sequence is identical to the low-pressure accident sequence of Section 3.2.1.
3.4.2 MOX Fuel Characteristics
The following fuel characteristics were specified for the MOX fuel.
* The MOX fuel pellets are 5% Pu0 2 with approximately 95% depleted U0 2. * The plutonium is approximately 93% Pu-239 and 6% Pu-240. * The cladding is M57. • The fuel assembly is identical to LEU assemblies, except for the fuel pellet. * The cycle length is 18 months. MOX assemblies are typically withdrawn after
two cycles. * The maximum burnup on an assembly basis is approximately 46 GWd/t * The typical burnup on an assembly basis is approximately 42 GWd/t • The burnup limit on a pin is 50 GWd/t. * The planned core loading is for approximately 40% MOX assemblies. * The MOX assemblies will be irradiated in 4-loop Westinghouse PWRs with ice
condenser containments.
Two differences between LEU and MOX fuels were noted. First, MOX fuel experiences high power at higher burnup levels. Second, the plutonium content of the discharged LEU fuel is approximately 1%. Note that MOX assemblies are discharged with an approximately 3% plutonium content.
MOX consists of a heterogeneous mixture of plutonium dioxide-rich particles dispersed in a uranium dioxide matrix. The plutonium dioxide-rich particles are expected to preferentially fission relative to the uranium dioxide matrix. As a result, voids will develop around the plutonium dioxide-rich particles and volatile fission products will accumulate in these voids. In addition, the uranium dioxide matrix adjacent to the voids is expected to be heavily damaged as a result of recoil of massive products of the fission process. These damaged regions and the voids about plutonium dioxide-rich particles will
7 M5 is an advanced cladding material with superior properties including corrosion resistance and low growth. M5 is currently planned to be used for MOX fuel
Energy Research, Inc. 36 ER!/NRC 02-202
create pathways for the"flow of fission product gases and vapors from fuel that is being
heated and degraded.
3.4.3 MOX Accident Source Term
The MOX releases into containment, as specified by the source term applicability panel,
are summarized in Table 3.12. A summary rationale was prepared for each'irelease
fraction, and this summary was reviewed by the panel. The resulting rationales for each
accident phase and for the duration and each radionuclide group are presented in Tables
3.13 through 3.21.
Numerous times 'during the elicitation 'of MOX- releases into the containment, panel
members emphasized that their input- was based upon partial and preliminary data
regarding MOX characteristics and behavior under severe accident conditions.
MOX releases were provided by all five-pinel members for the phase duration and for
the noble gases, halogens, alkali metals, and tellurium groups. However for the
remaining four groups (barium and strontium, noble metals, cerium group, and
lanthanides), some panel members elected to make no entry because it was felt that there
was insufficient' data available upon which to make an informed judgment. -The panel
members noted that most of the noble gases, halogens, alkali metals and tellurium group
are released from a MOX fuel. Thus, it was possible to make judgments as to the phase in
which they were released. However, f6r barium 'and strontium, the noble metals,- cerium
group, and lanthanides, only fractional releases occur and the database was deemed
insufficient by some panel members-to support a'specific value for a release fraction.
The NUREG-1465 values for PWR releases into containment are-shown in parentheses
for each phase and for the duration and each radionuclide group. For those cases for
which the panel agreed upon a single value, only'one value is entered (e.g., the duration
of the ex-vessel and late in-vessel release-phases). However, when the panel members
did not agree on a single value, one value was entered for each panel member.
A discussed in Section 3.1, the approach to specifying the source term in France differs
from that in the United States. A value is specified for the gap release. A second value is
specified for the in-vessel release. However, this latter value is the total release used for
the remainder of accident. Thus, value's for the ex-vessel and late in-vessel releases were
not provided for this effort. The total release values offered for the in-vessel phase of the
accident are flagged in the appropriate tables.
The panel only briefly considered additional MOX-specific research needs during the
course of its deliberations. As with the PWR and BWR source term, the panel members
were asked to document their opinions regarding research needs. The individual panel
member letters identifying research needs are provided in Appendix B.
ERI/NRC 02-202Energy Research, Inc. 37
Table 3.12 MOX Releases Into Containment 4
Gap Release Early In-Vessel Ex-Vessel Late In-Vessel Duration (Hours) 0.3; 0.4, 0.4; 0.4, 0.4 (0 5)' 1 4; 1.4; 1.4; 1.4; 1.5 (1.3) 2.0 (2.0) 100 (100)
Noble Gases 0 05, 0 05, 0 05; 0.05; 0 07 0.65; 0.65; 0.75; 0.93; 0, 0 2; 0.3, 0 3; TR (0) 0 (0) (0.05) 0.95 TR2 (0.95)
Halogens 0 05; 0 05; 0.05; 0.05; 0.07 0.325; 0.35; 0.35, 0.375; 0 15; 0.2; 0.25; 0.25; TR 0.2; 0.2; 0.2; 0.2; TR (0.1) (0.05) 0.95TR (0 35) (0.25)
Alkali Metals 0 05; 0.05; 0.05; 0.05; 0.07 0.25; 0.30; 0 30; 0 30; 0.65TR 0.25; 0.25; 0.30; 0.30; TR 0.10, 0.15; 0.15, 0 15, TR (0.05) (0.25) (0.35) (0.1)
Tellurium group 0; 0; 0; 0.005; 0.005 (0) 0.1; 0.15; 0.3; 0.35; 0.7TR 0.4; 0.4; 0.4; 0.4; TR (0.25) 0.1; 0 2; 0 2; 0 2; TR (0.005) (0.05)
Barium, Strontium NE3, NE, NE; 0, 0 (0) NE, NE, NE; 0.01; 0.1 (0.02) NE, NE, NE; 0.1; 0.1 (0.1) NE, NE, NE, 0; 0 05 (0)
Noble Metals (0) (0 0025) (0.0025) (0)
Mo, Tc NE, NE, NE; 0, 0 NE, NE, NE; 0.1; 0.1 NE, NE, NE, 0 01, 0 01 NE, NE, NE; 0.1; 0.1
Ru, Rh, Pd NE, NE, NE; 0; 0 NE, NE, NE; 0.05; 0.1 NE, NE, NE; 0.01; 0 01 NE, NE, NE, 0.01, 0 01
Cerium group (0) (0.0005) (0.005) (0)
Ce NE, NE, NE; 0; 0 NE, NE, NE, NE; 0.01 NE, NE, NE; 0.01; 0 01 NE, NE, NE; NE, 0
Pu, Zr NE, NE, NE, 0, 0 NE, NE, NE; NE; 0.001 NE, NE, NE; 0.001; 0.001 NE, NE, NE; NE; 0
Np NE, NE, NE; 0; 0 NE, NE, NE; NE; 0.01 NE, NE, NE, 0.01; 0 02 NE, NE, NE; NE; 0
Lanthanides NE, NE, NE; 0, 0 (0) NE, NE, NE; NE; 0.005 NE, NE, NE, NE, 0.01 (0 005) NE, NE, NE; NE; 0 (0) (0.0002)
The numbers in parenthesis are those from NUREG-1465, Accident Source Terms for PWR Light-Water Nuclear Power Plants (Table 3.13). 2 TR = total release. The practice in France is to not divide the source term into early in-vessel, ex-vessel, and late in-vessel phases. 3 NE = No entry; the panel member concluded that there was insufficient information upon which to base an informed opinion. 4 The values in Table 3.12 are for releases from the MOX assemblies m the core and not from the LEU assemblies.
Energy Research, Inc. 38 ERI/NRC 02-202
I II
F__ I�- F` F ` 1-7' 7 7-;
Table 3.13 Rationales for Duration Entries in Table 3.121
Gap Release The NUREG-1465 duration for this interval is 0.5 hr. The panel concluded that for MOX fuel, the duration of this
interval should be shortened. Four panel members specified a duration of 0.4 hr to indicate the direction of the change,
while still acknowledging the limited data available. Data from the VERCORS RT2 experiment as well as the Halden
data were considered by these panel members as a sufficient indication of trend to warrant a reduction in the length of the
period. Based upon the same information, one panel member specified a duration of 0.3 hr.
Needs: Data on duration of gap release and progression of fission gas loading of cladding for representative scenarios.
Early In-Vessel The NUREG-1465 duration for this interval is 1.3 hr. The panel members concluaea mat memetim to melt L uug ,L bottom head, i.e., the total of the gap release and early in-vessel phases, is the same for LEU and MOX at 1.8 hrs. Given,
that the gap release phase for MOX was shorter than for LEU, the early in-vessel phase duration was determined to last
1.4 hr. by four panel members and 1.5 hours by the remaining panel member.
Needs: MOX bundle degradation test to characterize fuel relocation and associated fission product transport.,
Ex-Vessel The NUREG-1465 duration' for this interval is 2 hrs. The panel concluded that the same value was applicable for MOX
fuel.'The ielease for this'phase is composed of two parts. The first is the continued degradation and expulsion of the core
rem iining w kithin'the vessel at the end of the early in-vessel'phase: The second is the release with the core-concrete
interacti6n." The panel felt that neither the early in-vessel release nor the release with core-concrete interactions were
changed by a'sufficient amount to change the duration of this phase.
Late In-Vessel The NUREG-1465 duration for this interval is 10 hrs. The panelconcluded that the same value was applicable for MOX
fuel. Resuslension and revaporization are the key processes for this phase 'of the accident: The 10 hr. period applies if,
the late in-vessel releases during this phase are the same ,as for LEU. However, if there are substantial releases of Te or'
SSr, these would enhance revaporization and could alter the duration of this phase.
I Panel member inputs for Table 3.13 and the remaining MOX rationale tables are based upon partial and preliminary data regarding MOX characteristics and
behavior available to the panel at the time the source term table input was prepared. , . , , I
ERI/NRC 02-202Energy Research, Inc.
I� -, F-- I... I
39
Table 3.14 Rationales for Noble Gases Entries in Table 3.12 Gap Release The NUREG-1465 gap release for LEU fuel was 0.05. A majority of the panel concluded that the same gap release was
applicable for MOX fuel and specified 0.05 as the release fraction to the containment Based upon the information presently available, these panel members concluded that the 0.05value for the release was still applicable. This value is based upon the database available to the panel, the limitations on burnup of MOX fuel, and a conclusion that while the MOX gap inventories for noble gases are higher than for LEU, they are still likely to be within the 0.05 level. One panel member concluded that the noble gas gap inventory was larger for MOX fuel and specified a value of 0.07.
Needs: For future large LOCA experiments, would recommend measurements of noble gases. Early In-Vessel The NUREG-1465 gap release for LEU fuel was 0.95, i.e., the entire inventory of noble gases was released during the
early in-vessel phase. One panel member concluded that the entire inventory of noble gases in MOX fuel was released in this phase and provided a release fraction of 0.93. Note that the gap release fraction offered by this panel member was 0.07. As noted in Section 3.1, The approach to specifying the source term in France differs from that in the United States. A value is specified for the gap release. A second value is specified for the in-vessel release. However, this latter value is the total release used for the remainder of accident. Thus, values for the ex-vessel and late in-vessel releases were not provided for this effort. The total release (TR) value for the noble gases was 0.95. The remaining panel members concluded that only a portion of the noble gases were released during the early in-vessel phase and that subsequent releases occurred dunng the ex-vessel phase. Two panel members estimated the release fraction to be 0.65, based upon an estimate of the amount of fuel either with failed cladding or melted down. One panel member estimated the release to be 0 75.
Ex-Vessel The NUREG-1465 ex-vessel release for LEU fuel was 0.0. Three panel members determined that there would be a release during this phase with two providing values of 0.3 and the third a value of 0.2. One panel member estimated the release to be 0. The final panel member was the French delegate and a release of 0 (TR) was specified per the French convention.
Late In-Vessel The NUREG-1465 late in-vessel release for LEU fuel was 0.0. The panel concluded the same value applied for MOX fuel.
Energy Research, Inc. 40 ERI/NRC 02-202
I- r_ F- F r-1
'T, 1l• : 1 •; P�tnn�1pc� fnr lnrn�n� Pntri� in T�,hle 112
[--- 7[ ' .-- F-
Energy Research, Inc.
Gap Release The NUREG-1465 gap release was 0.05. A majority of the panel concluded that the same gap release was applicable for MOX fuel and specified 0.05 as the release fraction to the containment. Based upon the information presently available, these panel members concluded that the 0.05 value for the release was still applicable. This value is based upon the database available to the panel, the limitations on bumup of MOX fuel, and a conclusion that while the MOX gap inventories for halogens are higher than for LEU, they are still likely to be within the 0.05 level. One panel member concluded that the halogen gap inventory was larger for MOX fuel and specified a value of 0.07.
Needs: The panel noted that there is essentially no data for halogen releases from MOX fuel and that data is needed.
Early In-Vessel The NUREG-1465 early in-vessel release was 0.35. Ex-vessel releases between 0.325 and 0.375 were specified by thl• panel members. One panel member concluded that the early in-vessel release was 0.325 based upon the observation that there is a higher deposition of vapors and aerosols on the piping system for MOX fuels and thus a smaller release fraction [33]. Two panel members concluded the halogen release fraction is 0.35, the same as for LEU. One panel member concluded that there were no significant changes in the assumptions associated with halogens releases from MOX fuel that would require a change in the release. The logic used by the second panel member considered both the fraction of MOX assemblies leaving the vessel as well as the LEU and'a total release of the halogens for.these materials to arrive at the 0.35 release. One panel member concluded that the halogens release was 0.375. The rationale was that for MOX there is a larger release than for LEU and at a faster rate. The numerical logic presented was based upon one-half the core in
LEU assemblies and the other half in MOX, assemblies. Melting and/or significant thermal damage to 70 percent of the core is taken and assuming a total release of the halogens, this leads to a release fraction of 0.35. Given the higher releases from the MOX, could lead to a value of 0.4 but this was reduced to 0.375 to account for the greater deposition rates. A total release or TR of 0.95 was specified by the French panelmember and this release was for the totality of the remaining scenario.
Needs: As with'the gap release, the panel noted that there is essentially no data for halogen releases from MOX fuel and
that data is needed. The panel also noted that data encompassing damage progression is crucial.
41 ERI/NRC 02-202
Table3.15 Rationales for Halogens Entries in Table 3.12 (continued)
Energy Research, Inc. 42 ERIINRC 02-202
I I
Ex-Vessel The NUREG-1465 ex-vessel release was 0.25. Ex-vessel releases between 0.15 and 0.25 were specified by the panel members, one at 0 15, one at 0.20 and two at 0.25. The value of 0.15 was specified based upon a calculation algorithm used by the panel member. The value of 0.2 was provided without a discussion of rationale. The panel members offering the value of 0.25 stated that they had no basis for changing the NUREG-1465 value. A total release or TR of 0 was specified by the French panel member as explained for the early in-vessel phase.
Needs: The panel identified the need for information about core damage progression and also for inventory data and data related to air ingress and revaporization.
Late In-Vessel The NUREG-1465 late in-vessel release was 0.1. The panel concluded that a value of 0.2 should be used for the late invessel release of MOX fuel, although different rationales were given. Two panel stated that they had no basis for changing the NUREG-1465 value, one based the value on the results a calculation algorithm, and the final number was provided with no discussion. A total release or TR of 0 was specified by the French panel member as explained for the early in-vessel phase.
Needs: The panel identified the of lack information on revaponzation but noted that this deficiency is not specific to MOX; the same deficiency also applies to LEU. The lack of air ingress data was also noted, i.e., the impact of air on the revaporization process.
Table 3.15
F __ ... "" F -. -.... F . . - - I -...r- I'.. .. F - - i " ...... r .
P�tr�i�1p� fnr Allr!lli M�t21� Pritries in Table 3.12
ERI/NRC 02-202Energy Research, Inc.
Gap Release The NUREG-1465 gap release is 0.05. Four panel members concluded that the same gap release was applicable for MOX
fuel and specified 0.05 as the release fraction to the containment. The rationale was that while the gap inventory is
probably a little highi-, the value of 0.05 has sufficient margin to reflect theincrease, paricularly when the burup is
limited to 40 GWd/t. One panel nmember, citing consistency with his contHbutions for the noble gases aind halogens
specified a highei'alkali metals gap invenitory of 0.07.
Early In-Vessel The NUREG-1465 early in-vessel release is 0.25. The alkali metals release fraction for MOX during the early in-vessel
phase is 0.30. All but one panel member stated that the MOX alkali metals release fraction is greater than for LEU. The
one panel member found no evidence that the NUREG-1465 number would not apply. A total release or TR of 0.65 was
specified by the French panel member and this release was for the totality of the remaining scenario.
Needs: The panel stated that the primary need was to understand the Cs data that currently exists from the VERCOR
program, Ex-Vessel The NUREG-1465 ex-vessel release is 0.35. Two panel members concluded the ex-vessel release was 0.25 and two panel
members concluded the release was 0.3. Rationales were not provided during the panel meeting. The final panel member;
was the French delegate and a release of 0 (TR) was specified per the French conventiohn
Needs: See gap release. Late In-Vessel The NUREG-1465 late in-vessel release is 0.1. One panel member concluded that the late in-vessel release was 0.10 and
three panel members concluded the release fraction was 0.15. No rationale was provided during the meeting for the 0.10.
value. For the 0.15 release fraction, it wag noted that the fractional releases of the alkali metals during the late in-vessel
phase are about the same as for NUREG-1465, but the environment is such that more deposition of cesium on' the parent
piping system is expected,'creating more refractory compounds, and reducing the efficiency of the reVaporization process.
The final panel member was the French delegate and a release of 0,(TR) was specified per the French convefition.
Needs: See gap release.
F . . I-- .. I - - ..... I - F ... .
"r',.•Kl,• '2 1
43
Rationales for Tellurium Group Entries in Table 3.12Gap Release
Early In-Vessel
Ex-Vessel
Late In-Vessel4-
______________________________________ I
The NUREG-1465 gap release is 0. For MOX fuel, three panel members concluded the gap release is 0. One noted that based upon its volatility, the tellurium releases should be as large as for the halogens. However, it also binds with the metallic elements in the fuel, reducing its volatility. Two panel members felt that a small gap release of 0.005 was appropriate.
The NUREG-1465 early in-vessel release is 0.05. Early in-vessel tellurium releases between 0.1 and 0.35 were offered by the panel members. Given MOX and M5 cladding, the panel member offering the 0 1 value expects slightly higher releases of molybdenum and ruthenium for MOX and the same for tellurium. However there will be higher concentrations of the reactive forms of tellurium in the release and these will interact with the surfaces, causing a significant fraction of the released products to be deposited on the piping system. The release fraction of 0.1 is the net of all these processes. A value of 0.15 was offered by another panel member who notes that there is an increased release relative to LEU but not as high as 0.3 offered by other panel members. Values of 0.3 and 0.35 were offered. No rationale was provided during the meeting for the former. For the latter, it was assumed that tellurium is released in the same amount as for the halogens and that the M5 cladding is essentially transparent to the tellurium. Given the M5 cladding planned for the MOX is a zirconium-niobium alloy rather than an alloy of zirconium and tin. Consequently tin telluride will not form during the degradation of fuel with this alloy. There are, however, silver indium cadmium control rods, which can react with the tellurium to produce silver telluride. A total release or TR of
0.7 was specified by the French panel member and this release was for the totality of the remaining scenario.
Needs- Data are needed on the interaction of MOX fuel and M5 cladding.
The NUREG-1465 ex-vessel release is 0.25. The panel concluded that a release rate of 0.4 applies to the ex-vessel release. One panel member noted that melt-concrete interactions are well understood as experiments have been done in which tellurium interactions were explicitly considered. The final panel member was the French delegate and a release of 0 (TR) was specified per the French convention.
Needs: See early in-vessel.
The NUREG-1465 late in-vessel release is 0.005. Three panel members concluded the late in-vessel release was 0.2 and one panel member concluded the release was 0.1. The rationale for the 0.2 release fraction was that a lot of tellurium is released from the fuel and deposited on the piping system during the earlier phases of the accident For reactors having air-filtered containments there will be air ingress and this will react to turn any tellurides into tellurium oxide, a volatile compound that will be released. The rationale for the 0.1 release was that once tellurium gets tied up on the surfaces, it won't subsequently be released (revaporized). The final panel member was the French delegate and a release of 0 (TR) was specified per the French convention.
Needs: See early in-vessel
Energy Research, Inc. 44 ERI/NRC 02-202
Table 3.17Table 3.17
F - F- F-'-F-F ['--- [F . . - I ...... . f'-
I able I.18 i aulln1ul i r i ui ai n Illl % L)lIUiLtJLutl s.tO t .
Gap Release The NUREG-1465 gap release is 0. Two panel members concluded that the gap releases for barium and strontium were 0.
They noted that the temperature is low and these species are not very volatile and will not vaporize at these temperatures. Two
panel members declared there was insufficient data to support a value. The French panel member also declined to provide a
specific value and stated that the analysis of applicable data was in progress but not yet to the point where the results could be
disseminated. Although a value was not entered, releases for which the on-going analyses might result in a change from the
NUREG-1465 value were "flagged" and a brief comment provided.
Need: Perform a LOCA test with MOX and measure the gap release.
Early In-Vessel The NUREG-1465 early in-vessel release is 0.02. Two panel members declared they were unable to provide a value'. The
French panel member also declined to provide a value but did describe two flags. The first flag was that data from PHEBUS
and data from VERCORS are not consistent. This is one of the areas currently being analyzed by the French. The second flag
was' that the results for sirontium have not yet been sufficiently analyzed. One panel member concluded that the early in-vessel
release fraction was 0.01 and noted that the fuel is inherently oxidizing, which would tend to suppress barium releases in
concer-t 'With incireasing noble' metals in response to the oxidizing environment. The stated release fraction was accompanied
by a statement thateonfidence in the value was low. One panel member concluded that a release of 0.1 'w's appropriate, ba~sed
upon obs'e-vwations and a 'onsideratioi of quialitati,'e irejresenta-ions of the French daia. 'Again', cnflfidenice in' the ;ahiit1kda's
said to be low. Ex-Vessel The NUREG-'1465 ex-vessel release is 0.1. Two panel members declared they were unable to provide a value. No~flags were
provided by the French panel member. Two panel members specified a release of 0. 1 and noted that the release is driven by Zr
p Ire s Iefie in thi6 initial transient. Zirconium reduces everything down to barium metal and barium metal vaporizes., ,
Late In-Vessel The NUREG-1465 late in-vessel release is 0. Two panel members declared they were unable to provide a value: No flags were 'provided by the French panel memb-er. Two panel maembers stated the releage was 0.°" The final panel member stated the
release was 0.05 beca-use his values for~releas'es from the vessel were large. - T,
The panel member elected to make no entry because it was felt that there was insufficient data available upon which to make an informed
judgment. The panel members noted that most of the noble gases, halogens, alkali metals and tellurium group are released from a MOX fuel.
Thus, it was possibleto make judgments" as to the phase in which they were released. However, for barium and strontium, the noble metals,
cerium group, and lanthanides, only fractional releases occur and the database was deemed insufficient by some panel members to support a
specific value for r *'rlease fraction.
r - *' -
ERI/NRC 02-202Energy Research, Inc.
F _- -... -.... . . .
ý I ý , I
•'•_1_1_ "• lt")
45
Table 3.19 Rationales for Noble Metals Entries in Table 3.12,-1 flI
Energy Research, Inc.
The NUREG-1465 gap release is 0. Two panel members concluded a release fraction of 0 was appropriate; no rationale was presented during the meeting. Three panel members declined to make an entry'. No flags were declared by the French panel member.
Early In-Vessel The NUREG-1465 early in-vessel release is 0.0025. The noble metal group was further subdivided into two subgroups, the first containing Mo and Tc and the second containing Ru, Rh and Pd. Three panel members declined to make an entry for the noble metals group.
For Mo and Tc, the remaining two panel members each concluded a release fraction of 0.1 is appropriate. The rationale provided for the release was that the uranium matrix surrounding the particles is where the fission products reside and this matrix oxidizes the fuel and creates the volatile forms of these radionuclides. The French panel member flagged this group to indicate that additional analysis was needed to determine if the value should be different than that specified for LEU fuel.
For Ru, Rh, and Pd one of the panel members concluded that a release of 0.05 is appropriate. The second panel member concluded that a release of 0.1 was appropriate.
Ex-Vessel The NUREG-1465 ex-vessel release is 0.0025. Two panel members declined to make an entry. The French panel according to the French approach to source term assigns a total release to the early in-vessel phase and does not declare values for the exvessel and late in-vessel phases.
For Mo and Tc the remaining two members each concluded that a release fraction of 0.01 is appropriate.
For Ru, Rh, and Pd the remaining two members each concluded that a release fraction of 0.01 is appropnate.
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kJap Release
46
F---- I- [ -" ** .. .[ F -- " F'-- I .. . F .... [ .. f ... F -P- [ ... F.. ... [
-3.19 Rationales for Noble Metals Entries in Table 3.12 (continued)
In-Vessel The NUREG-1465 late in-vessel release is 0. Two panel members declined to make an entry. The French panel according to
the French approach to source term assigns a total release to the early in-vessel phase and does not declare values for the ex
vessel and late in-vessel phases...
-For Mo and Te the remaining two members each concluded that a release fraction of 0.1 is appropriate.
For Ru, Rh, and Pd the'remaining two members each concluded that a release fraction of 0.01 is appropriate.
The rationale stated by one of the panel members was that MOX fuel is inherently oxidizing and that this would lead to
increased releases relative to LEU fuel.
The panel member elected to make no entry because it was felt that there was insufficient data available upon which to make an informed
judgment. The panel members noted tiat most of the noble gases, halogens, alkali metals ind tellurium group are released from a MOX fuel.
Thus, it was possible to make judgments as' to the, phase in which they were released. However, for barium and strontium, the noble metals,
cerium group, and lanthanides, only fractional releasesoccur and the database was deemed insufficient by, s0ome ianel membeis tio support a
specific value for a release fraction. -' .
, , ' , ,t
ERI/NRC 02-202Energy Research, Inc.
I
I ;
47
Gap Release The NUREG-1465 gap release is 0 Two panel members concluded a release fraction of 0 was appropriate; no rationale was presented during the meeting. Three panel members declined to make an entry'. No flags were declared by the French panel member.
Early In-Vessel The NUREG-1465 early in-vessel release is 0.0005. The cerium group was further subdivided into three subgroups, the first containing Ce, the second containing Pu, Zr, and the third containing Np. Four panel members declined to make an entry for the cerium group. The French panel member would separate Ce and Np from Pu. Flags were provided on both groups to indicate that the release fractions may change from those offered for high bumup PWR fuel.
For the Ce and Np groups, the remaining panel members concluded a release fraction of 0 01 is appropriate. Mechanical processes (e.g., in-vessel steam explosions, mass transfer from the fuel during relocation, etc.) were cited as the rationale for this release fraction.
For Pu, and Zr, the panel member concluded that a release fraction of 0.001 is appropriate. The reduced Pu release compared to the Ce release is a direct consequence of considering a low-pressure scenario. If a high-pressure sequence was being considered, the Pu release would be higher.
Ex-Vessel The NUREG-1465 ex-vessel release is 0.005. Three panel members declined to make an entry for the cerium group For Ce and Np, the remaining two panel members concluded a release fraction of 0.01 is appropriate This value is based upon molten-core-concrete-interaction experiments. For Pu, Zr, and Np the remaining two panel members concluded that a release fraction of 0.001 is appropriate. The rationale stated by one of the panel members was that MOX fuel is inherently oxidizing and that this would lead to increased releases relative to LEU fuel
Late In-Vessel The NUREG-1465 late in-vessel release is 0. Three panel members declined to make an entry for the cerium group. For Ce and Np, the remaining panel member concluded a release fraction of 0 is appropriate. F or Pu, Zr, and Np the remaining panel member concluded that a release fraction of 0 is appropriate.
The panel member elected to make no entry because it was felt that there was insufficient data available upon which to make an informed judgment. The panel members noted that most of the noble gases, halogens, alkali metals and tellurium group are released from a MOX fuel. Thus, it was possible to make judgments as to the phase in which they were released. However, for barium and strontium, the noble metals, cerium group, and lanthanides, only fractional releases occur and the database was deemed insufficient by some panel members to support a specific value for a release fraction.
Energy Research, Inc.
Table 3.20
I
48 ERI/NRC 02-202
F- [ t .. [ F I- - F - F-- F- F--- i
Table 3.21 Rationales for Lanthanides Entries in Table 3.12Gap Release The NUREG-1465 gap release is 0. Two panel members concluded a release fraction of 0 was appropriate; no rationale
was presented during the meeting. Three panel members declined to make an entry'. No flags were declared by the French panel member.
Early In-Vessel The NUREG-1465 early in-vessel release is 0.0002. One panel member concluded a release of 0.005 is appropriate. As a point of comparison, it was noted that the lanthanides display less volatility than the cerium group. Confidence in the stated value was said to be low. Four members of the panel declined to make an entry for the lanthanides. The French panel member flagged the release for Eu only to indicate that the release fraction for this radionuclide might change from the value specified for high bumup LEU fuel.
Ex-Vessel The NUREG-1465 ex-vessel release is 0.005. One panel member concluded a release of 0.01 is appropriate. Foun members of the panel declined to make an entry.
The rationale stated by the panel member was that MOX fuel is inherently oxidizing and that this would lead to increased releases relative to LEU fuel
Late In-Vessel The NUREG-1465 late in-vessel release is 0. One panel member concluded a release of 0 is appropriate. Four members of the panel declined to make an entry.
'The panel member elected to make no entry because it was felt that there was insufficient data available upon which to make an informed
judgment. The panel members noted that most of the noble gases, halogens, alkali metals and tellurium group are released from a MOX fuel. Thus, it was possible to make judgments as to the phase in which they were released. However, for barium and strontium, the noble metals, cerium group, and lanthanides, only fractional releases occur and the database was deemed insufficient by some panel members to support a specific value for a release fraction.
Energy Research, Inc.
F-- [---' I-- F-- I ---...... F-- F.... I--I-- F -- F -..
49 ERI/NRC 02-202
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4. INSIGHTS AND RECOMMENDATIONS
It is' noted that NUREG-1465 indicates that release fractions are intended to be
representative or typical, rather than conservative or bounding values, of those associated
with a low-pressure core-melt accident. The source term applicability panel employed the
same approach *in specifying the source -terms for high bumup LEU and -MOX fuels,
although each panel member provided his owfi release estimates, and in some-cases these
individual estimates may be considered as conservative ratherthan typical. Therefore,
the release 'fractions into the containment as recommnended herein are not expected to bound .all' potential severe accident scenarios, or to represent any single
"scenari6/seqieiice.
"It is noted that the panel did not have the benefit of the results of accident sequence
analyses using accident analysis models'validated by comparison t6 pertinent test results
involving highl burnup or MOX fuels. 'In addition, in many areas,ýthe panel identified
gaps in experimental data to support specific panel recommendations. Therefore, the
members of the panel have attempted to qualitatively integrate the results of recent tests
to predict fission product releases during accidents at'nuclear power plants. They hive
extrapolated. phenomenology of core degradation based on existing studies for
conventional bumup of LEU fuels to anticipate fission'product releases from fuel at
burnup levels in excess of about 60 GWd/t. The panel members have also extrapolated
the-behavior of LEU fuels with cohventional Zircaloy cladding to estimate the behavior
of mixed oxide fuel with zirconium-niobium alloy (M5) cladding.'
In formulating the proposed changes to the NUREG-1465 source term, for application to
reactor accident analyses for high bumup and MOX fuels, attention was'also given to the
changes in our understanding of LEU fuel fi~si6n product release that have c6me about
since-issuance of NUREG-1465 because 'of'major experimental investigations"bf fission
product behavior under' reactor accident conditions,' including the Phebus-FP and the
VERCORS experiments.
In general,'the results of the panel recommendations show that many of the proposed
changes to NUREG-1465 source terms are not applicable to 'the character of the fuel
"(high burnup or MOX fuel), but to new experthental data and/or the new interpretations
of the previously available data, on the part of the panel.
4.1 High Burnup Fuel
The proposed accident source terms-are listed in Tables 3.1 and 3.11, for application to
PWR and BWR design basis accident analysis; respectively.. Also shown in these tables
are the release -fractions as proposed in NUREG-1465 [1], forLWIs at lower levels of
,fuel burnup. ."
ERI/NRC 02-202SEnergy Research, Inc. 1,51
4.1.1 PWRs
The results of the panel recommendation for PWR high bumup fuel (Table 3.1) show that:
1. The release durations are not considered to be significantly different from the estimates in NUREG-1465. The shortened duration for the gap release phase reflects the expectation that the start of significant release of fission products is accelerated with high bumup fuel, as evidenced from the French VERCORS experiments. However, since the panel concluded that the total time for accident initiation to the end of the early in-vessel phase should be the same as the value in NUREG-1465, i.e., 1.8 hours, the duration of the "early in-vessel" phase was increased to 1.4 hours. The potential impact of fuel bumup on core damage progression has been recognized as an area requiring further integral experiments. The duration of release for the late in-vessel and the ex-vessel phases remain unchanged as compared with NUREG-1465.
2. An increase in the gap release, as compared to NUREG-1465, is noted only for the noble gases and the tellurium groups. This increase has been influenced by the experimental data of the Japan Atomic Energy Research Institute (JAERI) [9, 28].
3. The fission product releases in the early in-vessel phase show changes as compared with NUREG-1465 for all the fission product groups, except for the halogens, the alkali metals, and the barium/strontium groups. The reduction in the release of noble gas group reflects the current understanding that a near complete degradation of reactor fuel prior at the time of vessel breach is not considered to be plausible. Furthermore, the higher releases for tellurium as recommended by the panel, is influenced by the results of the Phebus experiments, and the importance of SnTe formation on the reduced tellurium retention (i.e., lower deposition rate as compared with elemental tellurium) within the reactor coolant system. The panel recommended regrouping the remaining nuclides to better reflect the differences in thermodynamic and chemical behavior of the various constituents in these groups. Higher releases are estimated for Mo/Tc; however, lower (as compared with Mo/Tc, but similar or higher as compared with NUREG-1465) releases are recommended for Ru, Rh and Pd. These release magnitudes were influenced by the observations from the French VERCORS experiments. Similarly, the panel also recommended dividing the cerium group into three subgroups consisting of Ce; Pu and fission product Zr*; and Np. Here again, due to the large uncertainties associated with the early in-vessel release of these nuclides, the range of releases to the containment assigned by the panel members spans over two orders of magnitude for Ce, and Pu/Zr; however, the majority of the panel members have suggested release magnitudes for Np which are higher than that in NUREG-1465 for the cerium group. The variability in the release estimates for the low volatile nuclides reflects the large uncertainties associated with these radionuclide groups. These changes as
Fission product Zr was moved from the lanthanide group due to very low volatility and the tetravalent nature of Zr
Energy Research, Inc. 52 ERI/NRC 02-202
recommended by the panel are independent of fuel burnup and are also applicable
to fuels at lower burnup levels.
4. The changes ,in the recommended releases for the late in-vessel and the ex-vessel
phases follow the observations as noted earlier for'the in-vessel phase, where
generally, no burnup dependence was noted. The most iiotable change is due to
higher potential for revaporization for halogens, tellurium and noble metal 'groups,
which are also expected to be applicable to lower burnup levels. The variations in
the panel recommended releases foir the low volatile liuclides as compared to
NUREG-1465 reflect the general uncertainties associated 'with the release of these
nuclides during core-concrete interactions, and are not indicative of expectations for
any significant burnup dependence.
4.1.2 BWRs
The panel recommended source terms to the containment for BWRs, were developed
considering the differences in BWRs and PWRs thai can impact the progressirn of severe
accidents, radionuclide releases and thieir'transport characteristics: The recommended
changes to the NUREG-1465 releases into BWR containmentIare also influenced by
factors such as the insights from the more recent experimental data, and the impact of
new fuel design, and not by differences due to the higher fuel burnup.
The results of the panel recommendations for BWR high burnup fuel as listed in Table
3.11 show that:
1. -The release durations are not considered to be considerably 'different from the
estimates in NUREG-1465, and the rationale for the shortened duration for the gap
release, and subsequently longer duration for the early in-vessel phase follows that
.-for PWRs discussed earlier.
2. As for PWRs, an increase in the gap release, as compared to NUREG-1465,jis also
noted for the noble gases and the tellurium groups.
3. The fission product releases in the early in-vessel phase show changes as compared with -NUREG-1465 for all the fission product groups, except for the
barium/strontium group. These. changes reflect more recent experimental
observations and the current expectation for more incomplete'core degradation prior
to vessel breach. Note that the range of recommended releases are similar to those
for PWRs as shown in Table 3.1 , except for tellurium group, where a lower estimate
for in-vessel release is recommended by the panel is due to the rationale'that the
core is kept in reducing conditions for longer times because of the higher zirconium
inventory and 'the oxidation of any boron carbide that is not dissolved by steel.
-'Here again, the recommended ,changes are not influenced greatly by'the change in
-fuel burnup, riather by the more recent experimental evidence and results of current
- ; code calculations.
ERI/NRC,02-202Energy Research, Inc. 53
4. The changes in the recommended releases for the late in-vessel and the ex-vessel phases follow the observations noted earlier for PWRs, where generally, no significant burnup dependence was identified. The most notable changes are due to higher potential for revaporization of the halogens, the tellurium and the noble metal groups, which are also expected to be applicable to lower burnup levels. As for PWRs, the variations in the panel recommended releases for the low volatile nuclides as compared to NUREG-1465 reflect the general uncertainties associated with the release of these nuclides during core-concrete interactions, and are not indicative of expectations for any significant burnup dependence.
4.2 MOX Fuels
An approach has been proposed to calculate the source term to containment for an entire core containing mixed oxide and low enriched uranium fuel assemblies (see Section 3.4 for details). This approach apportions the releases into the containment based on the fraction of the core that contains MOX (and LEU) fuel. The release parameters for the LEU part of the core are to be taken from Tables 3.1 or 3.11, depending on the reactor type; while, the release fractions for the MOX assemblies can follow the panel source term recommendations listed in Table 3.12.
Table 3.12 shows the range of panel recommendation for the various release parameters, reflecting the uncertainties due to lack of an adequate database to characterize radiological releases for MOX fuels.
In general, the duration of release for the various phases are essentially identical to the LEU fuels, with the general expectation that the gap release would occur over a shorter time period, based on the observations from the VERCORS RT2 and Halden test data.
Table 3.12 shows that some panel members concluded that there was insufficient information upon which to base an informed opinion, therefore, these panel members did not provide specific recommendations for the release fractions for other than the more volatile radionuclides. The panel members noted that most of the noble gases, halogens, alkali metals and tellurium group are released from a MOX fuel. Thus, it was possible to make judgments as to the phase in which they were released. For the remaining radionuclide groups, only fractional releases occur and the database was deemed insufficient to support a specific release fraction.
In general, the panel concluded that the gap release fractions are similar or slightly higher than those for LEU fuels.
The degree of variability in the recommended release parameters for noble gases, halogens, and alkali metals are not too different from those for PWRs and BWRs using LEU fuels. Nevertheless, some of the panel members were of the opinion that higher invessel releases (and faster rate of releases) are expected for MOX fuels as compared with LEU fuels. Note that some of the identified uncertainties are not specific to MOX fuels and are equally applicable to LEU and high burnup fuels (i.e., lack of data for effects of
Energy Research, Inc. 54 ERLNRC 02-202
revaporization and air ingression, which impact late in-vessel releases). The largest
quantitative differences are noted for tellurium, as compared with LEU, where the effect
of zirconium-niobium (M5 8) cladding- as currently planned for MOX fuels is the most
notable reasons listed by some of the panel members for the higher release fractions. In
addition, there is a general opinion that there will be a higher concentration of the
reactive forms of tellurium in the release, causing a significant fraction of the release to
be deposited on reactor coolant system structures, with a higher, propensity for late
revaporization (late in-vessel phase).
As in the case of LEU fuel, the variations in MOX fuel low volatile releases can be
substantial. Therefore, given the absence of MOX data, the panel members declined to
recommend estimates of quantitative release fractions.
Finally, there is a general expectation that the physical and chemical forms of the revised
source terms as defined in NUREG-1465 are applicable to high burnup and MOX fuels.
4.3 Panel Recommendations on'Research Needs to Confirm Changes to the
Revised Source Term
The limitations of the analysis and the available data make additional research to -confirm
the panel's estimates important. This section provides a summary of the -specific
recommendation by the panel members for research needs to confirm changes. to the
revised source term, as developed in the present report.
'The following specific research recommendations are extracted from the letters
reproduced in Appendix B, and ranked in accordance with the following prioritization
scheme:
High Priority- Research is required to develop confidence in' the proposed
releases to containment or permit such estimates to be made.
* Medium Priority - Research, -if conducted, should help reduce some'of the
uncertainties in releases to containment.
' • Low Priority - Research that is to help develop .a greater understanding of core
"degradation and fission product releases over the long-term, but not essential for
- use of the revised source term in licensing applications.
-High Priority
1. Acquire any available database on fission product release rates from high bumup and
MOX fuels, in order help the panel to update the panel recommendations included
herein. *This data will also help to parameterize the available fission product release
models in the 'systems codes used to analyze reactor accidents (see item 1 above).
B M5 is an advance cladding that is currently used in LEU fuel in the United States and Europe.
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2. Validation of accident analysis tools (i.e., MELCOR, VICTORIA) by comparison of predictions with results of major source term tests (e.g., PHEBUS-FP, VEGA and VERCORS with fuel of various bumup levels and MOX fuel) is needed. These comparisons that will lead to improvements and ultimately validation of the computer codes are essential steps before analyses of significant accident sequences using accident analysis tools.
3. Experimental investigation of in-vessel core degradation following vessel failure is important in verifying the impact of air-ingression on producing radically different source term (e.g., verification of the Canadian tests showing a nearly complete release of radioactive ruthenium in air). This is also an important issue for the assessment of spent fuel pool accidents, fuel transportation and dry cask storage of fuel.
4. Tests of core degradation with MOX fuel in order to assess damage progression behavior, including an assessment of the oxygen potential of MOX fuel in order to develop a better understanding of the chemical forms and volatility of various released constituents. These tests need to be performed with fuel rod bundles to investigate the fuel liquefaction, fuel relocation and fission product releases during the degradation process.
5. Applicability of MOX data and models needs to be established. In particular, the differences, if any, in the fuel degradation behavior between the MOX fuel that has been prepared with reactor-grade plutonium dioxide to the fuel that has been prepared from weapons-grade plutonium dioxide (of primary interest in the United States), need to be assessed analytically and/or experimentally.
6. Fuel burnup is expected to have an impact on the fuel melting point and fuel liquefaction process. The interaction of melting cladding with the fuel can be affected by the development of a restructured 'rim' region and by the formation of a significant oxide layer on the inner surface of the cladding. Perhaps of more significance is the possibility that the degradation of high bumup fuel will involve 'fuel foaming' rather than fuel candling as observed with fuel at lower burnup levels. This could change the core degradation process and consequently the release of fission products from the degrading fuel in qualitative ways that cannot be appreciated by simply extrapolating the results of tests with lower burnup fuel. Therefore, experimental investigation of fuel at high burnup, and with cladding material that include tin and niobium (Zirlo) or zirconium-niobium alloys (M5), are essential in confirming the radiological release characteristics (e.g., effects of tin in M5 cladding on tellurium release) of fuels at high burnup and with new cladding material.
7. Revaporization is an important element of the revised source term as documented in NUREG-1465 and the present report. The actual magnitude of the revaporization component depends on the vapor pressures of the deposited radionuclides and these vapor pressures depend on the chemical form of the deposited radionuclide.
Energy Research, Inc. 56 ERI/NRC 02-202
Unfortunately, there is a limited understanding of the chemical forms of the deposited
radionuclides. Consequently, empirical data' are required'on the vaporization of
deposited --adionuclides for comparison- with predictions of 'models of the
revaporization process.
Medium Priority
8. Perform separate-effects tests to resolve the issues of tellurium release; in particular,
the potential dependence of tellurium release on the interaction of tellurium with
Zircaloy (i.e., tin) in the cladding needs to be assessed experimentally.
9. Assess the accident sequence-specific aspects of release by considering thermal
hydraulic conditions other than low-pressure LOCA events in developing revised
source terms for licensing applications.
10. Analyses of risk significant accident sequences in reactors fueled with MOX that
follow a systematic code assessment process as recommended earlier (see item #2
above) for high bumup fuels.
11. The only BWR core damage progression test to date was DF-4. Yet one-third of the
U.S. fleet is BWR. Generally, it is thought that BWR core damage progression
phenomena can differ from PWRs (e.g., candling of melt vs. forming a crucible,
different control rod materials, larger amount of Zr which could make the accident
environment more reducing, lower power density). While these differences may not
make BWR releases substantially different from PWR releases (NUREG-1465 BWR
releases do not differ from PWR releases other than a small difference for iodine and
cesium), to the extent that additional Phebus tests are being contemplated, it makes
sense to consider having one of these tests be for BWR fuel.
Low Priority
12. The restructuring of high burnup fuel in the peripheral regions was identified as an
issue that could lead to higher gap inventories of volatile radionuclides and higher
release fractions of noble gases in the 'gap release' phase of an accident.
Information on the gap inventories of fission gases (Xe and Kr), certainly, and
possibly volatile radionuclides (Cs, I, and Te) and maybe even moderately volatile
radionuclides (Ba, Sr, Sb, Mo) might also be derived from work being done in the
Halden program on fuels taken to high burnup levels. If loss of coolant accident
(LOCA) tests of high burnup fuel are to be done, some effort should be made in these
tests to validate the predictions of the expert panel with respect to the gap releases
including the prediction that the gap releases of cesium and iodine would not be
affected significantly by high burnup. Tests with longer rods will also provide
information on the longer term fraction of the gap release fraction.
13. The understanding of fission product release during core debris interactions with
concrete is fairly complete. Refinement of this understanding and the predictions of
,Energy Research, Inc. 57 ERI/NRC 02-202
the release are not crucial for the revisions of the accident source term. This is true if for no other reason because the releases at this late stage of an accident are seldom used. Nevertheless, some of the known shortcomings of the codes used to predict the releases of fission products during core debris interactions with concrete should be addressed.
Energy Research, Inc. 58 ERVNRC 02-202
5. REFERENCES
1. L. Soffer, S. B. Burson, C. M. Ferrell, R. Y. Lee, and J. N. Ridgely, "Accident Source
Terms for Light-Water Nuclear, Power Plants," U. S.- Nuclear Regulatory
Commission, NUREG-1465 (1995).
2. U. S. Nuclear Regulatory Commission;- "Reactor Site Criteria," Title 10, Code of
Federal Regulations (CFR), Part 100.
3. U. S.' Nuclear Regulatory Commission; -"Assumptions Used for Evaluating the
Potential Radiological Consequences: of a Loss of Coolant Accident for Boiling
Water Reactors," Regulatory Guide 1.3, Revision 2 (June 1974).
4. U. S. Nuidlear -Regulatory Commission;- "Assumptions Used for- Evaluating the
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5. J. J. DiNunno et al., "Calculation of Distance Factors for Power and Test Reactor
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8. B. Clement and J. M. Evrard, "Part 3: Reassessment of Reference Source Terms,"
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9. A. Hidaka, T. Kudo, T. Nakamura and H. Uetsuka, "Overview and Progress of
VEGA, Program on Radionuclide Release from Fuel Under Severe Accident
Conditions," Japan Atomic Energy Research Institute (JAERI) Presentation to the
NRC Source Term Panel (September 24, 2001): -
10. R. J. White, et al., "Measurement and Analysis of Fission Gas Release from BNFL's
SBR MOX Fuel," Journal of Nuclear Materials 228, 43-56 (2001).
11. Y. Yan, T. S. Bray, H. C. Tsai and M. C. Billone, "High Temiperature Steam
Oxidation of Zircaloy Cladding from High Burnup Fuel Rods,'"' Proceedings of the
Twenty-Eighth Water Reactor Safety-Information, Meeting, NUREG/CP-0172, May
2001.
12. P. Blanpain,' "'MOX Fuel Fabrication," Experience -and Behavior," Framatome ANP
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13. "Technical Study of Spent Fuel Pool Accident Risk at Decommissioning Nuclear Power Plants," NUREG-1738 (October 2000).
14. H. P. Nourbakhsh, M. Khatib-Rahbar, and R. E. Davis, "Fission Product Release Characteristics into Containment Under Design Basis and Severe Accident Conditions," NUREG/CR-4881, (BNL-NUREG-52059), prepared for NRC by Brookhaven National Laboratory ( March 1988).
15. H. P. Nourbakhsh, "Estimates of Radionuclide Release Characteristics into Containment Under Severe Accident Conditions," NUREG/CR-5747, (BNLNUREG-52289), prepared for NRC by Brookhaven National Laboratory (November, 1993).
16. K. R. Jones, et al., "Timing Analysis of PWR Fuel Pin Failures," NUREG/CR-5787 (EGG-2657), prepared for NRC by Idaho National Engineering Laboratory (September 1992).
17. E. C. Beahm, C.F. Weber, and T. S. Kress, "Iodine Chemical Forms in LWR Severe Accidents," NUREG/CR-5732, (ORNL/TM-12229), prepared for NRC by Oak Ridge National Laboratory (April 1992).
18. "Severe Accident Risks: An Assessment for Five U.S. Nuclear Power Plants," U.S. Nuclear Regulatory Commission, NUREG-1 150 (December 1990).
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21. D. J. Alpert, D. I. Chanin, and L. T. Ritchie, "Relative Importance of Individual Elements to Reactor Accident Consequences Assuming Equal Release Fractions," NUREG/CR-4467, prepared for NRC by Sandia National Laboratories (March 1986).
22. F. T. Harper, et al., "Evaluation Of Severe Accident Risks: Quantification of Major Input Parameters, Experts' Determination of Source Term Issues," NUREG/CR4551, Vo12, Rev.1, Part 4 (June 1992).
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26. J. J. Carbajo, "Severe Accident Source Term Characteristics for Selected Peach
Bottom Sequences Predicted by the MELCOR Code," NUREG/CR-5942
(ORNI/TM-12229), prepared for NRC by Oak, Ridge National Laboratory
(September 1993).
27. B. E. Boyack et al., "Phenomena Identification and Ranking Tables (PIRTs) for Loss
of-Coolant Accidents in Pressurized and Boiling Water Reactors Containing High
Bumup Fuel," US Nuclear Regulatory Commission, NUREG/CR-6744 (December
2001).
28. T. Fuketa, H. Sasajima, and T. Sugiyama, "Behavior of High-Burnup PW'R Fuels
With Low-Tin Zircaloy-4 Cladding under Reactivity-Initiated-Accident Conditions,"
Nuclear Technology Vol.133, pp. 5 0-62, Jan. 2001.
29. T. Kudo, A. Hidaka, T. Nakamura and H. Uetsuka, "Influence of Pressure on Cesium
Release from Irradiated Fuel at Temperatures up to 2773K," J. Nucl. Sci. Technol.
Vol.38, No.10, pp.9 10 -9 1 1 (2001).
30. A. Hidaka, T. Kudo, T. Nakamura and H. Uetsuka "Enhancement of Cesium Release
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No.3, pp.2 7 3 -2 7 5 (2002).
31. A. Hidaka, T. Kudo, T. Nakamura and H. Uetsuka "Decrease of Cesium Release from
Irradiated Fuel in Helium Atmosphere under Elevated Pressure of 1.OMPa at
Temperature up to 2773K," J. Nucl. Sci. Technol. Vol.39, No.7, (2002).
32. J. Gieseke and H. Jordan, "Aerosol Deposition in BWR Steam Separators and
Dryers," Electric Power Research Institute, EPRI NP-5597, Research Project 2120-2,
Final Report (January 1988).
33. P. P. Malgouyres, M. P. Ferroud-Plattet, G. Ducros, C. Poletiko, M. Tourasse, and D.
Boulaud, "Influence of MOX Fuel in Fission Product Release Up to Meltdown
Conditions", Proceedings of NURETH-9 Meeting, San Francisco, California (Oct. 3
8, 1999).
34. D. A. Petti, et al., "Power Burst Facility (PBF) Severe Fuel Damage Test 1-4 Test
Results," US Nuclear Regulatory Commission, NUREG/CR-5163 (1989).
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APPENDIX A:
SOURCE TERM PANEL MEMBERS
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A.1 Panel Members
Dr. Bernard Clment Institut de Radioprotection et de Sfiret6 Nucl6aire
Dr. James Gieseke- Consultant Dr. David E. Leaver Polestar Applied Technology, Inc.' Dr. Thomas S. Kress Consultant Dr. Dana A. Power Sandia National Laboratories
A.2 Facilitator
"Dr. Brent Boyack Los Alamos National Laboratory
A.3 Yitae of Panel Members
"Bernard C16ment.
CV Not Available
James Gieseke
James A. Gieseke is currently an independent technical consultant specializing in fission
product trinsport and deposition,' and their'effect on nuclear' reactor safety. He obtained
his BS degree in chemical engineering from the University of Illinois in 1959, 'and his
MS and Ph.D. degrees in chemical engineering in 1963 and 1964, resp ctively,'from the
University of Washington.
The Battelle Memorial Institute employed Dr. Gieseke from 1963 through'1999 in a
varieiyof senior technical and management positions. His primary role was as program
manager for studies related to chemical measurement and aerosol behavior, the modeling
of fission 'product transport and deposition, and the 'development, and application of
measurement methods. Dr. Gieseke is" expert in a wide variety of disciplines including:
particle formation; interaction of particles with gases and 'with other particles;: design of
sampling and collection equipment; control and dispersion of particles within buildings;
and the analysis of gas and particle behavio6r in predicting fission pioduct transport and
deposition for nuclear safety studies.
Dr Gieseke was a principal contributor to the'report NUREG-0772, "Technical Bases for
Estimating Fission Prioduct Behaiior-during LWR Accidents" and was co-author of CSNI
SOAR No.l, "Nuclear Aerosols." He managed and participated in the development of
the HAARM,, QUICK, QUICK-M, and TRAP-MELT computer ctodes for predicting
"fission' product transport in nuclear reactor primary systems and containments,- was
responsible for -the development of the Source Term Code Package, and 'led the
pioneering integrated accident analyses f6r source term estimation as reported inBBMI
2104.
Energy Research, Inc. E1I/NRC, 02-20265
Dr Gieseke served as member of the NEA/CSNI's expert group on nuclear aerosols, the NRC's Expert Panel dealing with Source Term Issues for NUREG-1 150, and the NRC's MELCOR Code Peer Review Committee and VICTORIA Independent Peer Review Committee. He is author or co-author of approximately 70 technical papers, most of which focus on aerosol behavior and fission product transport as related to nuclear reactor safety.
David Leaver
David Leaver received his Bachelor of Science degree in electrical engineering from the University of Washington in 1965. He served as an officer in the U.S. Navy from 1966 to 1970, stationed at the Division of Naval Reactors, where he performed engineering work on naval nuclear plants. He received an MS degree in Engineering Economic Systems from Stanford University in 1973 and a PhD in Mechanical Engineering from Stanford University in 1975. His research involved economic strategies for plutonium recycle in light water reactors.
Dr. Leaver was employed at SAIC from 1975 to 1981 where he performed some of the earliest probabilistic risk assessment (PRA) studies of nuclear plants including the Clinch River Breeder Reactor Plant and the Big Rock Point plant. In 1982 he co-founded Delian Corporation, later acquired by Tenera, which provided engineering services to the nuclear industry. During this period, Dr. Leaver worked on PRA studies and participated in several independent assessments of nuclear plant operational and engineering readiness.
From 1987 to 1992, Dr. Leaver was heavily involved in development of safety, source term, and severe accident design requirements for the Advanced Light Water Reactor (ALWR). Under DOE sponsorship, Dr. Leaver established and led a team of experts in developing a more realistic design basis fission product source term to support ALWR plant design certification. This work directly led to a major NRC effort to update the source term regulations for advanced plants, and later for operating plants, resulting in the alternate source term (AST).
Since co-founding Polestar Applied Technology, Inc. in 1992, Dr. Leaver has been involved in a variety of source term-related work. He developed new methods for evaluating fission product aerosol transport in containment, which were successfully applied to the Westinghouse AP600 design basis source term. He developed improved methods for predicting aerosol retention in steam generator tube rupture and interfacing loss of coolant accidents, and applied these methods to develop a technical basis for reduced emergency planning zones in ALWRs. Dr. Leaver was the lead technical support for NEI efforts to develop a framework for applying AST to operating plants, and has performed safety-related calculations for over a dozen AST licensing applications. He also has been an instructor for courses on source term methods and applications held for interested utilities.
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Thomas S. Kress
Thomas S. Kress is past chairman of USNRC's Advisory'Committee on Reactor
Safeguards (ACRS) -and is currently servi'ng'his third term on that committee. He
acquired a BS and MS in Mechanical'Engineering and a PhD in Engineering Science
from the University-ofoTennessee. Before hisretireme'nt in 1994, he worked for 35 years
in various capacities at Oak Ridge National Laboratory (ORNL) where he wai'in,6olved
in design and safety aspects of LWRs, 'LMIFBRs, Molten-Salt 'Reactor, Gas-Cooled
Reactors, and Space Nuclear Applications. For several years, he managed ORNL's
Severe Accident Programs for NRC, which dealt with all aspects of core degradation and
source terms for LWRs. He was a member of OECD/CSNI Group of Experts on Source
Terms and Group of Experts on Aerosols. He helped develop a special source term
report for CSNI. He was a technical expert elicited for NUREG 1150 and helped NRC
develop NUREG-1465 (the current LWR design basis source term). He served as a
technical expert for IAEA's evaluation of the Chemobyl accident and, more recently,
helped develop an IAEA TECDOC on design basis source terms for future LWRs.
Dana A. Powers
D. A. Powers received his Bachelor of Science degree in chemistry from the California
Institute of Technology in 1970. He received a Ph.D. degree in Chemistry, Chemical
Engineering and Economics in 1975 from the California Institute of Technology. His
research for this degree program included magnetic properties of basic iron compounds,
catalyst characterization and the rational pricing of innovative products. In 1974, Powers
joined Sandia National Laboratories where he worked in the Chemical Metallurgy
Division. His principal research interests were in high temperature and aggressive
chemical processes. In 1981, he became the supervisor of the Reactor Safety Research
Division and conducted analytic and experimental studies of severe reactor accident
phenomena in fast reactor and light-water reactors. These studies included examinations
of core debris interactions with concrete, sodium interactions with structural materials,
fission product chemistry under reactor accident conditions, aerosol physics, and high
temperature melt interactions with coolant. Dr. Powers is the author of the VANESA
model of fission product release and aerosol generation during core debris interactions
with concrete. In 1991, Powers became the acting Manager of the Nuclear Safety
Department at Sandia that was involved in the study of fission reactor accident risks and
the development of plasma-facing components for fusion reactors. In this capacity, he
supervised the development of the VICTORIA model of fission product release and
transport in reactor coolant systems under accident conditions. Powers has also worked
on the Systems Engineering for recovery and processing of defense nuclear wastes and
has developed computer models for predicting worker risks in Department of Energy
nuclear facilities. Dr. Powers was promoted to Senior Scientist at Sandia in 1997. Dr.
Powers is the author of 103 technical publications.
From 1988 to 1991, Dr. Powers served as a member of the Department of Energy's
Advisory Committee on Nuclear Facility Safety (ACNFS). In 1994, he was appointed to
the Advisory Committee on Reactor Safeguards (ACRS) for the U.S. Nuclear Regulatory
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Commission. He was Vice Chairman of the ACRS in 1997 and 1998. He was elected Chairman in 1999 and 2000. In 2001, Dr. Powers received the Distinguished Service Award from the US Nuclear Regulatory Commission. Dr. Powers has served on committees for the National Research Council involved with the safety of Department of Energy facilities and the nuclear safety of reactors in the former Soviet Union. He has been an instructor for courses on reactor safety and accident management held by the International Atomic Energy Agency in several countries.
Energy Research, Inc. 68 ERI/NRC 02-202
APPENDIX B:
PANEL RECOMMENDATIONS ON RESEARCH NEEDS TO
CONFIRM CHANGES TO THE REVISED ACCIDENT SOURCE TERM
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Mr. Jason Schaperow February 27, 2002 U.S. Nuclear Regulatory Commission
-Mail Stop T-10-K-8- Washington, DC 20555
Re: Research Needs to Confirm Revisions to the Reactor Accident Source Term
Dear Mr. Schaperow:
Over the last several, weeks our panel has been developing revisions to the reactor
-accident source term described in NUREG-1465. This effort to develop revisions to the
reactor accident source term wereprompted by interest in having source terms applicable
to 'conventional reactor fuel taken to highburnups (55 to 75 GWd/t) and to mixed-oxide'
fuel (MOX) made with weapons-grade plutonium dioxide. In formulating the revisions,
however, attention was also given to the changes in our understanding that have come
about because of major experimental -investigations of fission product behavior under
reactor accident conditions such as the PHEBUS-FP, program, the VERCORS tests, and
VEGA tests. The assessments were done, however, without the benefit of -accident
sequence analyses using accident analysis models validated by comparison to pertinent
tests involving fuel taken to higher burnups or MOX.
Members of the panel developing the revisions to the NUREG-1465- source term have
attempted, then, to mentally integrate the results of specific, recent, tests to predict source
terms during accidents at nuclear power plants. They have extrapolated phenomenology
of core degradation known from studies of fuel taken to modest levels of burnup to
predict the source terms from fuel ;burned to levels in:excess, of about 60 GWd/t. The
panel members have also extrapolated , the - behaviors of conventional fuels with
conventional Zircaloy cladding to estimate the behavior of mixed, oxide fuel with
zirconium-niobium (M5) cladding.
The limitations of the analysis and databases available to the expert panel make research
to confirmi the panel's estimates important. I outline below what I believe to be important
confiriatory research to undertake to substantiate the experts' recommendations for changes to the reactor accident source term. I present these suggestions for research in
Energy Research, Inc. . ERI/NRC 02-202'--71
approximate priority order beginning with the highest priority tasks. In developing the priorities, I have been aware that the more used portions of the accident source term are
the gap releases and the in-vessel releases. I have also recognized that nearly all reactors
now plan to take fuel to very high levels of burnup (at least 60 GWd/t and perhaps,
someday, as high as 75 GWd/t), whereas only two reactors now plan to use mixed oxide
fuel. A different approach to the prioritization could alter the order of the list. Especially
the priority of work on mixed oxide fuel issues could be changed if different criteria had been used.
Task 1: Validate accident analysis tools by comparison of predictions with results of major source term tests.
A new generation of accident analysis tools, notably the MELCOR code9 and to a lesser
extent the VICTORIA code'0 , are available for predicting reactor accident source terms.
These tools have been developed based on research that led to the NUREG-1465 source
term and research that has been done since this source term was published. These tools
have not been validated, however, by comparison of their predictions with the results of
major tests in the PHEBUS-FP program including the recent FPT-2 test involving reduced coolant flow and the FPT-4 test involving radionuclide release from debris
expected to form in the later stages of core degradation. Comparisons of code predictions
to the results of VERCORS tests with fuel of various burnups and mixed oxide fuel
fabricated with reactor-grade plutonium dioxide need also to be done. These comparisons that will lead to improvements and ultimately validation of the computer codes are
essential steps before the next high priority, confirmatory research task - analyses of
significant accident sequences. Specific code comparison that are needed include
comparisons of code predictions to the results of the FPT-I, FPT-4 and FPT-2 integral
tests from the PHEBUS-FP program. More detailed comparisons to separate effects tests
from the VEGA test program and VERCORS test program may be needed to properly
parameterize models of radionuclide release from the degrading fuel.
The test results now available for comparison with code predictions have a distinct bias
toward pressurized water reactor accident conditions. This has been in the past a
significant concern since so few data directly applicable to accidents in boiling water
reactors are available. This concern is being ameliorated in recent years as fuel and fuel
configurations used in boiling water reactors have evolved to become more like the fuel
9 R.O Gauntt, et al., MELCOR Computer Code Manuals, NUREG/CR-6119, Volumes 1 and 2, SAND 2000-2417/1,2, Sandia National Laboratories, Albuquerque, NM, December 2000. 10 N.E. Bixler, VICTORIA 2.0: A Mechanistic Model for Radionuclide Behavior in a
Nuclear Reactor Coolant System Under Severe Accident Conditions, NUREG/CR613 1, SAND93-2301, Sandia National Laboratories, Albuquerque, NM, December 1998; T.J. Heames, et al., VICTORIA: A Mechanistic Model of Radionuclide Behavior in
the Reactor Coolant System Under Severe Accident Conditions, NUREG/CR-5545,
SAND90-0756, Revision 1, Sandia National Laboratories, Albuquerque, NM, December 1992.
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and fuel configurations found in pressurized water reactors. An approximation that has
been made in developing the recommendations that follow is that boiling water reactor
specific data are not needed. That is, phenomenological tests recommended below will be
suitable for validating codes for analysis of accidents in either pressurized water reactors
or ,boiling water reactors. Explicit validation of this assumption is probably needed at
some point. .
Task 2: Reanalyze risk significant accident sequences using the validated accident
analysis tools.
The original NUREG-1465 accident source term was developed based on examination of
a variety of accident analyses most of which were done with the old Source Term Code
Package. Similar sets of analyses obtained using improved, validated analytic tools need
to be the basis of the revisions to the accident source term. One really must use accident
analyses to define the source terms rather than the results of tests. Releases of
radionuclides depend on time and temperature as well as accidentphenomena. The times
-and temperatures of reactor accidents are not ,usually mimicked in tests to the accuracy
needed to estimate source terms. Crucial issues that'need to be considered' in these
analyses include:
S -- fraction of the core that remains within the core region following rupture of the
reactor pressure vessel; this will have significant implications onthe nature of
.the source term following vessel rupture. I .evidence from that the tests that fuel relocation, gas flow and ga.s composition
are as important as fuel temperature in determining the rates of radionuclide
releases. • maximum temperatures reached by fuel prior to liquefaction and relocation
which will have important ramifications on the release of the more 'refractory
radionuclides. S "development of regions and periods of steam starvation in the core region
which will affect the vaporization of alkaline earths (Ba, Sr) as well as
refractory radionuclides such as Ce, Pu, and La. releases of tellurium (Te), molybdenum,(Mo) and ruthenium (Ru).
" • -duration of core debris retention in the reactor pressure vessel.
An important outcome of these analyses will be, determination of the need to draw
,additional- distinctions within classes -of, radionuclides such as the distinctions drawn
between Mo and Ru in the noble metal group and between Ce and Pu in actinide group.
Predictions of prolonged retention of core debris within the reactor vessel might
necessitate some changes in the timing of the accident source, term and even the
definition of new regimes of release.. : . - - -
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Task 3: Experimental investigation of invessel core degradation following vessel rupture.
Modem accident analyses appear to predict with great consistency that a substantial fraction of the reactor core remains within the core region after reactor pressure vessel failure. The degradation of this residual fuel following penetration of the reactor vessel by core debris has been the subject of some speculation recently but little detailed analysis. The degradation of this fuel is often known as the 'air ingression' issuell
because it is likely that air will interact with this fuel following vessel failure. Air interactions with the residual fuel has the potential of producing a radically different source term based on results of tests in Canada showing nearly complete release of radioactive ruthenium in air 1. But, we suspect that there is a competition between the rate of fuel liquefaction by interaction with molten cladding and fuel oxidation leading to extensive releases of ruthenium and tellurium. Competition arises because the reaction of air with the fuel cladding produces so much heat that it is possible that the fuel will melt and relocate from the core region before there is an opportunity for extensive fuel oxidation and releases of radioactive ruthenium and tellurium. This competition probably cannot be resolved based strictly on analysis. Experimental investigations will be needed. Experimental studies of this later phase of the core degradation process would not ordinarily rise so high in priority, but air interactions with fuel are also important to issues of spent fuel pool safety, fuel transportation and dry cask storage of fuel. These needs in combination with the significant potential change in the ex-vessel stage of the accident source term, experimental studies of core degradation in air are recommended with high priority.
Task 4: Acquire any available data base on fission product release rates from high burnup fuel.
The purpose of this task is to assemble data suitable for the parameterization of models of fission product release used in accident analysis codes to account for the effects of elevated bumup. To be useful, the data must be for fuel that has sufficiently high bumup that a significant 'rim' region of restructured fuel has developed. This typically means that the fuel pellet average bumup must exceed about 55 GWd/t and should preferably be in excess of 70 GWd/t. The data that are most useful are for semi-volatile and low volatile fission products. (Volatile fission products such as Cs and I are essentially completely released by fuel that is heated to the point of liquefaction and relocation. Details of the release rates for these volatile species are, then, less crucial to the accurate
11 D.A. Powers, L.N. Kmetyk, and R.C. Schmidt, A Review of the Technical Issues of Air Ingression During Severe Reactor Accidents, NUREG/CR-6218, SAND94-0731, Sandia National Laboratories, Albuquerque, NM, September 1994. 12 F.C. Iglesias, C.E.L. Hunt, F. Garisto, and D.S. Cox, "Measured Release Kinetics of Ruthenium from Uranium Oxides in Air", Proceedings International Seminar On Fission Product Transport Processes During Reactor Accidents, J.T. Rogers, editor, Hemisphere Publishing Corp., Washington, D.C., 1990.
Energy Research, Inc. 74 ERI/NRC 02-202
estimation of release fraci6ns for the revised accident s'-'rce term.) The best data will "involve at least two temperature plateaus,-where substantial release occurs so that temperature dependencies can be determined.
Task 5:,- Experimental investigations of core degradation with high burnup fuel.
The profound, qualitative differences between the degradation of unburned uranium dioxide fuel and fuel that has been taken to burnups of 30-40 GWd/t have been
remarkable. Even though bumup only modestly affects the melting point of the, fuel, burnup very seriously affects the liquefaction of the fuel. Similar qualitative changes in the degradation of fuel that has experienced very high burnup are possible. Clearly, the
interaction of ,melting clad with the fuel can ,be affected by the development of a restructured 'rim' region and by the formation, of a significant oxide layer on the inner surface of the cladding. Perhaps- of more significance is the possibility that the degradation of high burnup fuel will involve 'fuel foaming' rather thanýfuel candling as
observed with fuel at lower burnups. Fuel foaming even if it is important only for transient periods could change the core degradation process and consequently the release
of fission products from the degrading fuel in qualitative ways that cannot be appreciated by simply extrapolating the results of tests with lower burnup fuel.
The suitability of the fuel for tests ofhigh bumup fuel degradation are similar0to those mentioned above. That is, the fuel must have a well-developed 'trim' structure. Tests with
fuel having an average bumup of about 70 GWd/t would be preferred. Another issue of
importance is the choice of cladding. Until now most tests of core degradation have been
done with Zircaloy clad fuel. It appears that many licensees are migrating toward cladding alloys involving both tin and niobium (Zirlo) or zirconium-niobium alloys (M5).
Tests of core degradation with high burnup fuel should be done with a type of cladding that will get widespread use in the future.
Task 6: Analysis of accident sequences involving high burnup fuel.
Once reliable, validated accident analysis models are available, a range of representative accident sequences 'must be analyzed -to develop, a base of information from which
.*accident source terms may be derived. The range of accident sequences must include both
pressurized water reactors and boiling water- reactors. The range must also in'lude-the range of patterns for loading fuels of various levels of burnup into the reactor core. An effort must be made to identify those things that qualititively affect the progression of
core damage and the releases of fission products to the containment.
* Task 7: - Revaporization Tests , ., .
A sage feature of the NUREG-1465 source term is the recognition that fission products
deposited in the reactor coolant system my revolatilize later in the accident. The inclusion
of this long-term, late source of radionuclides to the containment has been based on
analyses. The actual magnitude of the revaporization source term will depend on the
vapor pressures of the deposited radionuclides and these vapor pressures depend on the
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chemical form of the deposited radionuclide. Unfortunately, we have a limited understanding of the chemical forms of the deposited radionuclides. Experimental determination of the chemical forms of radionuclides on surfaces is quite difficult because concentrations can fall below the limits of common methods for determination of chemical form. Consequently, empirical data are required on the vaporization of deposited radionuclides for comparison with predictions of models of the revaporization process.
The tests that are needed involve heating deposits of radionuclides from prototypic surfaces in flowing atmospheres of the type to be expected in the reactor coolant system late in accident sequences. Such atmospheres could be quite oxidizing if the reactor coolant system has been penetrated by core debris and air circulates by natural convection through the reactor coolant system. Temperatures that need to be investigated are modest and certainly do not exceed the melting point of steel or even the temperatures at which heavy sections of steel creep rapidly.
Fortunately, it is probably not necessary to develop new test plans for the study of revaporization. Some revaporization tests are planned for the PHEBUS-FP program. Assuming that these tests do not fall victim to limitations of the budget, the tests should involve the revaporization of radionuclides from rather prototypic mixtures of deposited materials. It is, however, still important that once these test results come available that they are compared to predictions of models and appropriate adjustments to the models be made. Then, the models have to be used to predict the release fractions from revaporization in risk significant accident sequences.
Task 8: Separate-effects tests to resolve the issues of tellurium release.
The release of tellurium from degrading reactor fuel remains a mystery. Based on its physical and transport properties, tellurium should be as volatile as cesium and iodine from overheated reactor fuel. It is found, however, in some tests that tellurium release is greatly inhibited - as though it were interacting with the clad and would not release until the clad has been extensively oxidized. In other tests, it appears that tellunum is bound within the fuel matrix in some form that exhibits limited volatility. In the recent PHEBUS-FP tests, there is evidence of rather extensive tellurium release, but this release may have been delayed either until sufficient cladding oxidation has occurred or until sufficient fuel oxidation or degradation has occurred.
It appears some experimental resolution of this state of limited understanding of tellurium release is required. The need for this resolution may be even greater if there is an evolution within the nuclear industry away from cladding with high tin content to cladding made with zirconium alloyed with elements that interact less strongly with tellurium than tin.
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Task 9: Acquire any test data on the release of fission piroducts from MOX fuel.
The purpose of this task is to provide the data needed to parameterize the models of
fission product release to account for the unique feature of mixed oxide fuel (MOX). The
requirements for useful data are similar toiliose discussed for a similar task in connection
with high bumup fuel (Task 4, above). The best data are for the modestly volatile and low
volatile species such as Ba, Mo, Ce, etc. The tests should involve at least two temperature
,plateaux where significant (measurable) releases occur so that temperature dependencies
can be determined. At least some useful, data are available from the VERCORS
program13 underway in France, though it may be necessary to obtain additional data to
properly parameterize the models of release especially for the releases 'of actinides such
as Pu, Cm, and Np. Releases of these actinides have been the subject of some public
concern over the plan to use MOX in commercial nuclear power plants14.
Task 10: Tests of core degradation with MOX fuel.
There are not test data now on the degradation of MOX fuel under accident conditions.
Because the interaction of the cladding with MOX could be quite different than the
interaction of cladding with conventional fuels, it is possible that degradation of MOX
- could be quite different than the degradation of conventional reactor fuels. Indeed, MOX
may be more susceptible to fuel foaming types of degradation thani candling degradation
Sbecause of the high gas content of localized, plutonium-rich regions of the fuel. Such
qualitative changes to the degradation process will affect the release fractions of fission
products in a systematic way. Tests-are needed, then, of the degradation of MOX. Such
tests need to be done with fuel rod bundles to investigate the liquefaction and relocation
of fuel. Fission product releases during the degradation process need to be monitored.
Task 11: -Applicability of MOX data and models.
Data on fission product release from MOX fuel and degradation of MOX fuel will come,
almost assuredly,- from MOX that has- been prepared -with -reactor-grade plutonium
,dioxide rather than weapons-grade plutonium dioxide that will be of priniary interest in
the United States. There may be other differences. For example, 'some'e hiave suggested
- that the size distribution of plutonium dioxide rich particles within the fuel to be used in
the US will be different than the size distribution of particles in fuel prepared in Europe.
Analyses or tests must be done, then, to confirm that data obtained with one type of MOX
fuel are adequate, perhaps with some corrections, to adequately understand the.behavior
(degradation and radionuclide release) of the type of fuel of primary interest. Whether
this task can be done analytically, or requires,prototypic testing really cannot -be
- 13 p.p. Malgouyres, M.P. Ferroud-Plattet, G. Ducros, C. Poletiko, M. Tourasse, and D.
Boulaud, "Influence of MOX Fuel in Fission Product Release Up t60Meltdown
* Conditions", Communications at the NURETH 9 ANS Meeting. 14 E.S. Lyman, Public Health Consequences of Substituting Mixed-Oxide for
Uranium Fuel In Light-Water Reactors, Nuclear Control Institute, January 21, 1999.
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adjudicated until there are more data on some types of MOX fuel and some better phenomenological understanding of the things that most affect MOX behavior under accident conditions.
Task 12: Analyses of risk significant accident sequences in reactors fueled with MOX.
Task 12 is much like task 6 for high burnup fuel and task 2 for general changes to the source term. Once reliable, validated models of core degradation involving MOX and fission product release from MOX are available, these codes must be used to analyze representative accident sequences for the plants that will use the MOX. This task is simplified by the fact that today only Westinghouse pressurized nuclear power plants in ice condenser containments will use MOX. The task is complicated, however, by the need to consider a range of patterns for the loading of MOX into the core, perhaps a range of MOX concentrations in fuel, and ranges of fuel burnup. The analyses of the representative accident sequences will provide the information in which a meaningful accident source term can be derived.
Task 13: LOCA tests with high burnup fuel.
The expert panel argued that restructuring of high burnup fuel in the peripheral regions should lead to higher gap inventories of volatile radionuclides and higher release fractions of noble gases in the 'gap release' phase of an accident. Information on the gap inventories of fission gases (Xe and Kr), certainly, and possibly volatile radionuclides (Cs, I, and Te) and maybe even moderately volatile radionuclides (Ba, Sr, Sb, Mo) might also be derived from work being done in the Halden program on fuels taken to high burnup levels. But, inventories are not easily translated into gap release fractions. If loss of coolant accident (LOCA) tests of high burnup fuel are to be done, some effort should be made in these tests to validate the predictions of the expert panel with respect to the gap releases including the prediction that the gap releases of cesium and iodine would not be affected significantly by high burnup. Such validation is complicated by the loss of gap inventory in the refabrication of rods for the tests. This can only be addressed by attempting to measure or estimate the loss of inventory. It may not matter whether tests are done with single rods or with multiple rods. More important will be the length of the rod. The gap release is composed of a prompt inventory venting and a longer term gap diffusion fraction. Releases from short rods will be dominated by the inventory venting. Tests with longer rods will also provide information on the longer term fraction of the gap release fraction.
Task 14: Upgrade models of fission product release during core debris interactions with concrete.
The understanding of fission product release during core debris interactions with concrete is fairly complete. Refinement of this understanding and the predictions of the release are not crucial for the revisions of the accident source term. This is true if for no other reason because the releases at this late stage of an accident are seldom used. Nevertheless, there
Energy Research, Inc. 78 ERI/NRC 02-202
are some nagging anachrohmsms in current codes used to pre'dict these releases of fission
products during core debris interactions with concrete. For example, it is known that the
existing models underpredict the releases of ruthenium observed in tests because of
inaccurate partitioning of ruthenium among the phases of core debris and omission of an
important vapor species. The codes may also overpredict the releases of alkaline earths
(Ba and Sr) because of improper activity coefficients. If resources are available some limited effort to correct these code deficiencies should be undertaken.
Sincerely yours,
Dana A. Powers Senior Scientist Nuclear and Risk Technologies Center Sandia National Laboratories Albuquerque, NM 87185-0744
cc:
R. Gauntt, SNL R.Y. Lee, NRC M. Khatib-Rahbar, ERI B. Boyack, LANL
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March 13, 2001
Mr. Jason Schaperow U.S. Nuclear Regulatory Commission Mail Stop T-10-K-8 Washington, D.C. 20555
Dear Jason,
In the third meeting of the panel addressing the NUREG-1465 update for high burnup
and mixed oxide (MOX) fuels, it was -requested that panel members submit a letter
discussing research needs. This letter is to provide my thoughts on this matter. In
preparing this letter, I have received input from or discussed this subject with Duke
Energy, the Electric Power Research Institute (EPRI), and Polestar people with
experience in source term phenomena.
To address research needs, two categories of data have been considered:
(1) Data which could be made available in the short-term and used for the ongoing
NUREG-1465 update for high burnup and MOX fuels
(2) Longer-term research which would be confirmatory, or which may be of interest
to stakeholders
Observations on Short-Term Research
In the first category, there are several issues which have been discussed by the panel and
which warrant discussion here:
French MOX fuel fission product release data From information presented by the French
representatives, it is evident that there are significant data available on MOX accident
releases. These data include that from VERCORS RT 2 (can be compared to RT 1) and
VERCORS RT 7 (can be compared to HT 1). This would very likely be the most cost
effective, and only short-term, way' for NRC to obtain MOX fuel accident release data.
The panel should have the benefit of revievWing this data before concluding its work on
the NUREG-1465 update if at all possible. Tables for RT 1, RT 2, and RT 7 similar to the
HT 1 table entitled, "VERCORS HT1: FP release balance," which was in the French
presentation would be very useful.
Oxygen Potential of MOX Fuel Figure 2. of reference [1] shows oxygen potential vs.
temperature for LEU fuel materials. While significant differences are not expected, it
would be useful to make some estimates of how the oxygen potential for MOX fuel (i.e.,
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PuO 2 rich agglomerates in a U0 2 matrix) compares with this figure. As fuel damage progresses, oxygen potential of the damaged fuel is determined by the H2/H20 ratio in the gas space in the core region. Assuming chemical equilibrium exists at the high core region temperatures, oxygen potentials required for formation of oxides of various core materials can be used to assess fission product chemical form. The chemical form of a material (metal vs. oxide) affects its volatility.
Phebus FPT-2 data Phebus FPT-2 was performed in October, 2000. While data analysis takes significant time, perhaps a quick look report of FPT-2 release data could be made available to the panel in the next few months. One interesting qualitative observation from FPT-2 is the fact that the Te release was quite low compared to FPT-1.
Weapons uade (WG) MOX vs. reactor p'ade (RG) MOX This matter was raised as a possible concern regarding the applicability of French MOX source term data, which is for RG MOX, to the U.S. Material Disposition program which will use WG MOX. The following is noted regarding RG MOX vs. WG MOX:
I
"* Per reference [2], the MOX fuel fabrication process (master blend mix) will be adjusted for WG MOX fuel to produce plutonium-rich particles with approximately the same fissile content as RG MOX plutonium-rich particles, consistent with the European experience base. Thus the fission density and the fission product inventory will be the same in WG and RG MOX.
" The WG MOX fuel composition and neutronic performance tends to be in between that of RG MOX and low enriched uranium (LEU) fuel. This is illustrated in Figures 7.4 to 7.8 in reference [2].
" The ongoing Advanced Test Reactor (ATR) WG MOX fuel tests have progressed beyond 30,000 MWD/t with no indication of differences between WG MOX fuel and RG MOX fuel. These tests have included destructive hot cell post-irradiation examination (PIE) at intermediate burnups. The tests are to be continued to a bumup of 50,000 MWD/t, including additional hot cell PIE.
" The DCS Fuel Qualification Plan includes a WG MOX fuel lead assembly program prototypical WG MOX fuel assemblies in one of the McGuire or Catawba reactors. The plan calls for irradiation of at least one assembly for three cycles (burnups in excess of 50,000 MWD/t), and hot cell PIE approximately one year following the third cycle. The hot cell PIE is intended to be confirmatory in nature - i.e., the NRC would issue a license for batch-scale irradiation of MOX fuel prior to the PIE.
Based on the above, the matter of WG vs. RG MOX is likely to be a second order effect for source term and need not be considered for additional research in the short-term. The ATR and MOX fuel lead assembly programs should be monitored to confirm that the data do not indicate significant differences between WG and RG MOX fuel.
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Observations on Longer-Term Research
Effect of M5 Clad Mat6rial The MOX fuel assembly desigii will employ M5 cladding.
M5 is an advanced bi-metallic (zirconium-niobium, no tin) cladding material. There was
speculation at the last meeting regarding the effects of M5 clad on source term, the main
possible effect being on Te release.
There are several points relevant to this discussion:
"* With tin present in the clad, for low clad oxidation the Te can be sequestered as
SnTe in the unoxidized clad, thus limiting the Te release. However, even with tin,
high local oxidation (such as the 85% active clad oxidation in FPT-1) can drive
much of the SnTe out from the oxidized region. "* This clad sequestering effect will not be present without tin. In this case there are
three possibilities: (1) the Te is in a reactive form (elemental Te oir H2Te) which
will significantly increase the Te deposition velocity and thus decrease Te release,
(2) some of the Te reacts with other materials such as silver (for PWRs with AgIn-Cd control rods) which results' .in sequestering, or (3) some of the Te reacts
with silver aerosol to form Ag2Te aerosol which behaves like SnTe
"* A final point is that use of M5 clad (and thus the absence of tin) is not exclusively
a MOX fuel source term issue since M5 is being used in operating plants in the
U.S. (LEU fuel) and Europe today.
Thus, use of M5 clad would not be expected to increase Te release, and in fact may
decrease it. This, together with the fact that the M5 issue exists for LEU fuel, suggests
that if research is performed on the effect of M5, it be done in the context of LEU fuel.
Such research need not impact the ongoing MOX source term effort.
Non-LOCA events The panel's scope is limited to LOCA release. The gap release
fraction is a relatively small part of the LOCA source term, most of the release being fuel
release. Thus, changes in the gap release will not have a major effect on the total release
for the LOCA. This is not the case for non-LOCA events (such as-FHA, locked pump
rotor, MSLB, SGTR, rod ejection) where most if not all of the release is the gap.
Furthermore, these non-LOCA events involve different thermal conditions which can
affect release: FHA involves a cool rod; locked pump rotor, MSLB, and SGTR involve a
slowly heated rod; and rod ejection involves a rapidly heated rod. Thus, at some point in
the future the NRC should consider updates for the non-LOCA releases.
BWR fuel release The only BWR core damage progression test to date was DF-4. Yet
one-third of the U.S. fleet is BWR. Generally, it is thought that BWR core damage
progression phenomena can differ from PWRs (e.g., candling -of melt vs. forming a
crucible, different control rod materials, larger amount of Zr which' could make the
accident environment more reducing, lower power density). While these differences may
not make BWR releases substantially different from PWR releases (NUREG-1465 BWR
releases do not differ from PWR releases other than a small difference for iodine and
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cesium), to the extent that additional Phebus tests are being contemplated, it makes sense to consider having one of these tests be for BWR fuel.
MOX core damage progression There was discussion at the last meeting on the possible need for a MOX fuel core damage progression test. Such a test is considered low priority based on the following:
" The MOX fuel assembly design is a state-of-the-art fuel assembly design by Framatome. A very similar design (without M5) was used for more than a decade in the McGuire and Catawba units, and is currently being used at Sequoyah. The same design (except for fuel pellet material) will be deployed at the North Anna units in about one year. Other than fuel pellet material, there is nothing special about the fuel assembly design, relative to LEU PWR fuel.
"* MOX fuel has only small differences in thermal properties compared to LEU fuel (slightly lower decay heat, slightly lower thermal conductivity, slightly higher specific heat below -2300 K, slightly lower specific heat above -2300 K, slightly higher fuel temperature). These differences would not be expected to cause significant differences in severe accident behavior of MOX fuel compared to LEU fuel.
"* The only aspect of MOX fuel which could impact severe accident progression is the fuel pellet microstructure (i.e., the occurrence' of Pu fissions in PuO2 rich agglomerates in the U0 2 matrix). However, this impact is expected to be minor since pellet microstructure will have little or no effect once fuel melting begins. In addition, any potential effect of MOX fuel is mitigated by the fact that the core is predominantly LEU fuel.
In any event, the VERCORS data, oxygen potential information, and the PIE from ATR WG MOX fuel irradiations noted above in the short-term research discussion should be used in deciding the priority of any MOX tests.
I appreciate the opportunity to provide this input for NRC consideration. Please contact me with any questions or comments.
Very truly yours,
David E. Leaver
Cc: Steve Nesbit, Duke Energy Jack Haugh, EPRI
References
1. R.R. Hobbins et al, "Fission Product Release from Fuel Under Severe Accident Conditions," Nuclear Technology, Vol. 101, Pages 270 - 281, March, 1993
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2. Duke-Cogema-S&W (DCS), "Fuel Qualification Plan," Prepared for U.S.
Department of Energy, Office of Material Disposition, DCS Document Number
DCS-FQ-1999-001, Rev. 2, transmitted to NRC on April 16, 2001.
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March 20, 2002
Mr. Jason Schaperow US Nuclear Regulatory Commission Mail Stop T-1 0-K-8 Washington DC 20555
Dear Jason,
As requested during the third meeting of the Source Term Applicability Panel, I am
submitting this letter to provide you with my thoughts concerning research'needed to
reduce uncertainties in the panel's estimates of reactor accident source terms. The focus
of the panel has been on PWR and BWR designs containing conventional nuclear fuel
that has been taken to high levels of burnup (approximately 50 to 75GWd/t) or reactors
using a mixed-oxide fuel(MOX). The prime objective was to provide accident source
terms in the same manner as those presented in NUREG-1465, but for the high burnup
and MOX fuels. Inherent in the. process -was the inclusion of updates to the basic
understanding of fission product release and transport that have come about subsequent to
the issuance of NUREG-1465.
The process carried out by the panel has been basically one of updating the NUREG
1465 fission product release information through'consideration of the differences inherent
in the fuels being considered. In support of these deliberations were experimental data
provided to the panel, largely from VERCORS and VEGA tests and from PHEBUS-FP
studies. Unlike the information base available for producing NUREG-1465, there have
not been computations and related data interpretations devoted to analyses of the high
burnup and MOX situations.
As one considers research needs, it is evident that gap and early in-vessel releases are
typically of most concern and depend largely on releases from the fuel in th e core region.
One could then focus only on limited or simple experimental release studies, but it is
important to note that other factors come into.play. Such factors would 'include, for
example, the chemistry differences among -fuel/cladding systems which could'have a
pronounced effect-on reactions and subsequent retention of fission products within the
core region. Therefore, the interests and concerns go beyond just gap and vaporization
type releases and must extend more broadly into solid and gas phase chemistry issues. It
becomes obvious that complex, as well as simple, experiments must be performed and it
is my opinion that these need to be coupled with and supported by at least a limited
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modeling or computational effort to promote understanding. Only from such a combined approach will we be able to achieve any substantial reductions in uncertainties in fission product releases.
It is possible to consider several levels of activities. An immediate benefit should result from gaining access to and interpretating data from the French VERCORS and PHEBUSFP studies which were not available to the panel. Coupled with computer model predictions, these data may provide an immediate boost in the panel's knowledge base, which in turn could lead to added confidence in estimated release fractions. Because of a general lack of data, most of the panel members were either unable to or were uncomfortable in providing predicted releases for MOX fuel at accident times much beyond gap releases and most expressed some uneasiness in making predictions for the high bumup situations. This points out the major need for significant experimentation with high bumup and MOX fuels if uncertainties in estimated fission product release are to be reduced.
It is worth noting that in comparison to this paucity of directly pertinent experimental data and related' computational results for high bumup and MOX fuels, information of this type for conventional fuel applications had been generated in decades of research and was available for the preparation of NUREG-1465. Of course this database still exists and is useful, mainly as a baseline, but is insufficient for extension to the cases being considered in this current update of NUREG-1465.
The objective of the remainder of this letter is to identify some data and research results that would reduce uncertainties in the fission product release estimates. In some cases, added information would allow for estimates to be made where previously none have been deemed possible. The intent is to identify needs and not to specify research programs, although it is not possible to entirely separate the two in a practical sense. In many cases the necessary extent of any research program can only be defined as progress is being made. That is, the success of each incremental improvement in understanding of a physical phenomenon will be reflected in some reduction in uncertainty of fission product release estimates. The need then for added research efforts must continually be balanced against the need for reducing the residual uncertainties.
Computer Codes/Modelin2
The information base for NREG-1465 included selected calculations used to assist in estimating release fractions and in establishing the duration of the various release periods (gap, early in-vessel, ex- vessel, and late in-vessel). Results from many of these computations are also being used in the current work. However, specific accident analyses were not available for this current study; the reason being that it was assumed that differences in timing and release rates could be estimated by comparison with and modification of the NUREG-1465 results. This is largely true, but there are some areas where a supporting computational effort would have been and could still be found helpful.
Energy Research, Inc. 88 ER.UNRC 02-202
One major area of interest would be to produce selected predictions of releases from
core-concrete interactions that reflect changes in fuel/core composition. This would
include estimations of the importance on ex-vessel release of cladding composition for
the M5 (and-perhaps Zirlo if deemed prevalent enough) clad relative to Zircaloy. In a
parallel effort, the same sort of chemical composition effects should be inv~estigated
computationally for the early in-vessel release. There are a variety of codes that could be
exercised but it should be most useful-for the NRC if the VICTORIA and MELCOR
codes are included in these efforts. First principle release codes have largely been found
to be unsuccessful and are not suggested for application in this area. This is because even
in the -most practical applications they seem to end up with more undefined parameters
than can ever be evaluated experimentally. On the other hand, correlations of data
employing simplifications of overall physicochemical processes are preferred.
Computer models that predict fission product release and transport can be also-be useful
to -an-experimental program. First, predictions made with the various codes can help
establish sensitivity of experimental results to -input variables and thus help : select
experimental conditions to be studied. Second, thie application 'of the codes to analyze
experimental results can help interpret the experimental results. For these reasons there is
a need for a computational effort to accompany and interact with experimental studies.
Finally, the various fission release-and transport models implicit in the codes can be
,improved through comparison with experimental results and subsequently modified, as
needed. An effort in this area should be ,undertaken in the future as understanding of the
physicochemical processes grows. It is important to note that experimental results are not
directly applicable to reactor accident analysis. It is only through the application of a
complex code, built up from various individual physical and chemical models, that the
overall estimated impact of any accident scenari' can be assessed.
MOX Fuel Examination/Characterization
It is expected that data on fission product release from MOX fuel will come from
European studies using fuel made using reactor grade plutonium dioxide rather than the
weapons grade plutonium oxide that is planned for use in fabricating MOX fuel for US
reactors. There are expected to be differences between the two fuels and whether these
differences can be significant is an issue. It seems prudent to blunt any questions
regarding the usefulness of the available data buy performing sufficient analyses to
resolve the issue. It may be necessary only to make simple physical comparisons of fuel
cross-sections for the two fuels at various burnups. However, it is important to reach a
published decision on the comparability of the two fuels in order to maintain the integrity
of any estimates of fission product release rates that are based on use of the European
data. If the fuel comparisons are made at some point too far in the future, and if the
comparisons find fuel differences that are deemed significant, it is possible that the
fission release data will need be evaluated again. It seems advisable to make fuel the
comparisons early enough to avoid repeating research efforts.
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Fission product release and transport
The most critical research need to help reduce uncertainties in estimates of fission product source terms will be for experiments that produce data on fission product release. The panel found uncertainties in estimated releases to be greatest for fission product categories: barium/ strontium, noble metals, cerium group, and lanthanide group. There was also an expressed lack of understanding of tellurium behavior. As a result, these fission products are of most interest in any experimental fission product release study. Of course, a full complement of data giving releases for all groups is needed if meaningful comparisons with previous release studies are to be possible.
Experimental studies should be performed as part of the VERSORS experiments or carried out in a similar fashion. The focus should be on release from the fuel as a function of LEU fuel burnup as well as on experiments to distinguish the effects of fuel type (MOX vs LEU). Appropriate choices of cladding must accompany these fuels or be studied as variables (whether it be Zircaloy, Zirlo, or M5). Also needed are sufficient PHEBUS-FP experiments to provide understanding of in-core processes such as chemical interactions of fission products with cladding, with other core materials, with various surfaces and among themselves. Of major interest are the effects of fuel degradation, melting and motion on the release rates and chemistry. A portion of this work may have already been done successfully and a first step would be to review the data as they become available. The quality of the data, how the data compare with other previously available data, and the extent to which uncertainties must be reduced will guide the selection and need for specific added experiments.
I hope that my opinions as expressed above contain suggestions that the NRC finds useful, and will help focus attention on the types of research needed to reduce uncertainties in the estimated source terms.
Sincerely,
James A. Gieseke 3930 Smiley Road Hilliard OH 43026
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